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KIM, SUNG JOON (김성준)
Graduate Institute of Ferrous Technology(철강대학원)
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MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:1||High temperature cracking:1||STRESS RELIEF CRACKING:1||ACIDIC SULFATESOLUTIONS:1||toughness:1||tensile test:1||Xray micrograph:1||PLASTICFLOW:1||BUFFER SOLUTION:1||8.5 BUFFER SOLUTION:1||PASSIVATION:1||ASSISTED CRACKPROPAGATION:1||SUBSTRUCTURE:1||PERMEATION:1||Microhardness:1||Critical dissolution current density:1||EQUILIBRIUM SEGREGATION:1||SURFACE:1||Febased alloys:1||SEM scanning electronmicroscopy:1||SURFACEANALYSIS:1||Ductiletobrittle transition:1||Brittle fracture:1||impact test:1||NEUTRONDIFFRACTION:1||high nitrogen steel:1||MNC SYSTEM:1||FE:1||tensile properties:1||GRAINSIZE:1||TRIP STEEL:1||High nitrogen stainless steel:1||Synergistic effect:1||HOT DUCTILITY:1||Lath martensitic stainless:1||AISI 304L:1||STATE:1||FILM:1||Interfaces:1||Electron microscopy:1||Stacking fault energy:1||Martensitic transformation:1||EPSILON MARTENSITE VARIANTS:1||neutron diffraction:1||WELDING PROCESS:1||AUSTENITE DECOMPOSITION:1||DIMENSIONAL ANISOTROPY:1||TRIP steel:1||intercritical annealing:1||Advanced high strength steels:1||Deformation and fracture:1||Plasticity:1||DEFORMATION MICROSTRUCTURE:1||welding:1||PART II:1||FATIGUE:1||Polarization test:1||MOLYBDENUM:1||CHROMIUM:1||INDUCED MARTENSITE:1||AUSTENITIC CRMNCN STEELS:1||FECR:1||strain rate:1||PHOSPHORUS:1||frictionstir welding (FSW):1||EBSD:1||GRAINSTRUCTURE:1||nitrogen:1||passive film:1||TENSILE:1||Metal forming and shaping:1||MECHANICALPROPERTIES:9||TRIP STEELS:8||DEFORMATIONBEHAVIOR:7||GRAINBOUNDARY SEGREGATION:6||MICROSTRUCTURE:6||RETAINED AUSTENITE:5||STAINLESSSTEELS:5||IRON:5||MODEL:5||PHASETRANSFORMATIONS:5||KINETICS:4||BEHAVIOR:4||SI:4||CARBONSTEEL:4||Hot press forming:4||ALLOYS:4||MARTENSITICTRANSFORMATION:4||Springback:4||HEATTREATMENT:4||NITROGEN:4||STRESS:4||NONEQUILIBRIUM SEGREGATION:4||ALLOY:3||CONSTITUTIVE MODEL:3||FRACTURE:3||Austenitic steel:3||METALS:3||STAINLESSSTEEL:3||TEMPERATURE:3||MULTIPHASE STEELS:3||TRANSFORMATION:3||EMBRITTLEMENT:3||metals:3||Stainless steel:3||ALUMINUM:3||Grain boundary segregation:3||MN:2||HYBRID MEMBRANE/SHELL METHOD:2||Magnesium alloy sheet:2||PHOSPHORUS SEGREGATION:2||carbon:2||Mechanically induced martensite transformation:2||CLASSICAL PLASTICITY:2||AL:2||Asymmetry:2||FORMING PROCESS:2||BAINITE:2||Nitrogen:2||fracture:2||deformation twinning:2||DUCTILE SINGLECRYSTALS:2||TEXTURE EVOLUTION:2||Elastoplasticity:2||Analytical solution:2||PLASTIC ANISOTROPY:2||PREDICTION:2||TRANSVERSE CRACKING:2||XPS:2||Thermodynamics:2||LOWTEMPERATURES:2||KurdjumovSachs relationship:2||Transformation plasticity:2||PRECIPITATION:2||DEFORMATION:2||CARBON:2||Crystal plasticity finite element method:2||ferrous metals:2||CYCLIC PLASTICITY:2||BRITTLEDUCTILE TRANSITION:2||PITTING CORROSION:2||TOUGHNESS:2||Martensite:2||SIMULATION:2||DISLOCATION:2||SLIP:2||Transformation induced plasticity (TRIP):2||LOWCARBON STEELS:2||INTERFACIAL SEGREGATION:2||Hardenability:2||Tool design:2||Finite element method:2||SHEET:2||Passive film:2||CREEP CAVITATION:2||SULFUR:2||sheet metal:2||hot press forming:2||springback:2||Steels:2||Precipitation:2||MULTIPHASE CARBONSTEELS:2||Finite element analysis:2||DEPENDENCE:2||FINITEELEMENT MODEL:2||Utility ferritic stainless:1||APPLIED TENSILESTRESS:1||Steel:1||ACIDSOLUTIONS:1||CLEAVAGELIKE FRACTURE:1||alloys:1||grain refinement:1||RETAINED AUSTENITE STABILITY:1||pitting corrosion:1||PHOTOELECTROCHEMICAL ANALYSIS:1||Characterization:1||HIGHTEMPERATURE BEHAVIOR:1||LOWALLOY STEEL:1||Passivation potential:1||Fracture:1||brittletoductile transition:1||Ductiletobrittle transition temperature:1||Grain size:1||annealing:1||BORATE BUFFER:1||Highnitrogen austenitic steels:1||Austenitic steels:1||Neutron diffraction:1||DISLOCATION INTERACTIONS:1||FCC>:1||HCP TRANSFORMATION:1||SILICON:1||stainless steels:1||CHEMICALLY BANDED 5140STEEL:1||EXTERNALLY APPLIED STRESS:1||Corrosion:1||FILMS:1||microstrucutre:1||PASSIVITY:1||Delta ferrite:1||COMPUTERSIMULATION:1||Highnitrogen:1||corrosion:1||TENSILE DEFORMATION:1||shear texture:1||microstructure:1||MICROTEXTURE:1||TOOL:1||deformationinduced martensitic transformation:1||general corrosion:1||Carbon:1||PASSIVE FILMS:1||ELECTRONICPROPERTIES:1||Passive films:1||Iron alloys:1||Stress/strain measurement:1||INDUCED PLASTICITY STEEL:1||Nickel:1||Pitting corrosion:1||NICKEL:1||Postweld heat treatment:1||Thermal tensile stress:1||Intergranular failure:1||AUSTENITIC STAINLESSSTEEL:1||CORROSION BEHAVIOR:1||AUSTENITIC STEELS:1||PASSIVE FILM:1||CYCLIC VOLTAMMETRY:1||Deformationinduced martensite:1||Austenite stability:1||Twinning:1||PLASTICDEFORMATION:1||galvanization:1||AXIAL STRESSES:1||TRANSFORMATION PLASTICITY:1||Phase transformation:1||Hole expansion ratio:1||Tensile properties:1||Metals and alloys:1||ENVIRONMENT EMBRITTLEMENT:1||AES:1||dendrite boundary cracking:1||Toughness:
