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KIM, NACK JOON (김낙준)
Graduate Institute of Ferrous Technology(철강대학원)
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BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:2||ultrafinegrained lowcarbon steel:2||equal channel angular pressing (ECAP):2||TRANSMISSION ELECTRONMICROSCOPY:2||HIGHSTRAIN:2||multiple shear band:2||tensile properties:2||die casting:2||minimum creep rate:2||GAMMATITANIUM ALUMINIDES:2||dropweight tear test (DWTT):2||boride:2||SECONDARY RECRYSTALLIZATION:2||CRYSTAL STRUCTURES:2||TENSILE DEFORMATION:2||Tensile deformation:2||bainitic steels:2||strength:2||DAMAGE:2||fracture:2||Twin:2||INDUCED MARTENSITICTRANSFORMATION:2||C ALLOYS:2||Bulk metallic glass:2||reactive spray forming:2||thermomechanical processing:2||SHEETS:2||CLOSURE:2||PHASEDIAGRAM:2||API X70 linepipe steel:2||PREDICTION:2||magnesium alloys:2||fracture toughness:2||ZMA611:2||6061 Al alloy:2||HIGHTENSILE STRENGTH:2||HARDNESS:2||anisotropy:2||API 5L3 specification:2||TRANSITIONTEMPERATURE REGION:2||pore:2||WEARRESISTANCE:2||LAYERS:2||INTERFACE REACTIONPRODUCTS:2||entropy:2||Characterization and Evaluation of Materials:2||Twinning induced plasticity (TWIP):2||work hardening:2||scanning electron microscopy:2||toughness impact test heat affected zone:2||ADDITIONS:2||Composite:2||SEGREGATION:2||high strain rate:2||tensile creep:2||GAMMATITANIUM ALUMINIDE:2||inverse fracture:2||dendrite:2||spray distance:2||QUASICHEMICAL MODEL:2||PIPELINES:2||loadrelaxation test:2||AISI 4340 STEEL:2||BOUNDARIES:2||PLASTICDEFORMATION:2||LAMELLAR STRUCTURE:2||BARRIER COATINGS:2||TEMPERATURETRANSFORMATION DIAGRAM:2||INTERMETALLIC COMPOSITES:2||abnormal fracture appearance:2||HIPping:2||A356 aluminum alloy:2||MICROSTRUCTURAL MODIFICATION:2||Nanotechnology:2||RESIDUALSTRESSES:2||Ironphosphorus:2||MAGNESIUM:2||grain refinement:2||MN:2||DEGRADATION:2||Surface segregation:2||THERMODYNAMIC FUNCTIONS:2||Duplex lightweight steel:2||scanning electron microscopy (SEM):2||Heat affected zone:2||Cup forming test:2||DELAYED FRACTURE:2||lamellar:2||creep:2||dispersion strengthened Cu alloys:2||MG:2||DUALPHASE STEEL:2||RESISTANCE:2||CRACK INITIATION:2||LITHIUM:2||KINETICS:2||energy transition temperature:2||bulk metallic glass alloy:2||simulation:2||Swift equation:2||Al2O3ZrO2 oxide:2||atmospheric plasma spraying:2||stainless steel blend coating:2||hightoughness pipeline steel:2||welding pores:2||INITIATION:2||CU47TI34ZR11NI8:2||Twinning induced plasticity steels:2||Surfaces and Interfaces:2||HYDROGEN EMBRITTLEMENT:2||TOTALENERGY CALCULATIONS:2||BLACK PHOSPHORUS:2||C STEEL:2||DUCTILE:2||DEFORMATION TWINS:2||Delayed fracture:2||PERFORMANCE:2||SILICON:2||PROPERTY:2||GAMMATIAL ALLOY:2||API X70 pipeline steel:2||CA:2||ALALLOY:2||nanopowder:2||Al2O3TiO2 oxide:2||critical cooling rate:2||ELEVATEDTEMPERATURE APPLICATIONS:2||highenergy electronbeam irradiation:2||adiabatic shear band:2||annealing:2||LOCALIZATION:2||crack deflection:2||electron beam:2||surface alloying:2||TITANIUMALLOYS:2||vanadium carbide:2||Solidification:2||recrystallization:2||{100} <:2||ORIENTED SILICON STEELS:2||BEHAVIOR:73||MICROSTRUCTURE:40||MECHANICALPROPERTIES:37||DEFORMATION:24||TENSILE PROPERTIES:19||ALLOYS:18||METALLICGLASS:14||TOUGHNESS:13||PHASE:13||DEFORMATIONBEHAVIOR:12||MICROSTRUCTURES:12||TRANSFORMATION:12||COMPOSITES:11||strip casting:11||STACKINGFAULT ENERGY:10||CARBON STEELS:10||TEMPERATURE:10||ACICULAR FERRITE:10||ALUMINUM:10||DUCTILITY:10||STEEL:9||microstructure:9||PLASTICITY:9||SYSTEM:9||SUPERCOOLED LIQUID:9||TRIP/TWIP STEELS:9||rolling:8||MAGNESIUM ALLOYS:8||BULK METALLIC GLASSES:8||wear resistance:8||GLASSFORMING ABILITY:8||MORPHOLOGY:7||ALLOY:7||COPPER:7||STAINLESSSTEEL:7||STRENGTH:7||bulk amorphous alloy:7||NUCLEATION:7||Magnesium alloys:7||amorphous alloy:7||AMORPHOUSALLOYS:6||LOWCARBON:6||TITANIUM:6||metals:6||crystalline phase particle:6||AL ALLOYS:6||IMPROVEMENT:6||FRACTURE:6||LIQUID:5||API X80 linepipe steel:5||ROOMTEMPERATURE:5||MAGNESIUM ALLOY:5||MATRIX COMPOSITES:5||FABRICATION:5||IRON:5||CARBON:5||rapid solidification:5||SHEET:5||highenergy electron beam irradiation:5||AZ31:5||surface composite:5||WAVE BASISSET:4||NANOCRYSTALLINE POWDERS:4||DESIGN:4||SOLIDIFICATION:4||Mg alloy:4||effective grain size:4||ZR41.2TI13.8CU12.5NI10.0BE22.5:4||COATINGS:4||AUSTENITE:4||CREEPPROPERTIES:4||surface alloyed material:4||Texture:4||Tensile properties:4||MARTENSITICTRANSFORMATION:4||METALS:4||plasma spray coating:4||TRIP STEELS:4||ZR:4||shear band:4||sintering:4||highcycle fatigue:4||FE:4||metamorphic alloy:4||GROWTH:4||Ti6A14V:4||STRETCH FORMABILITY:4||ALUMINUMLITHIUM ALLOYS:4||FRACTURETOUGHNESS:4||CRACKPROPAGATION:4||Microstructure:4||Highstrength bainitic steel:4||EQUATION:4||RETAINED AUSTENITE:4||investment casting:3||EB weld:3||Mg alloys:3||TiAl:3||PIPELINE STEELS:3||STABILITY:3||ductility:3||TRANSITIONS:3||SI:3||PHASES:3||CRYSTALLIZATION:3||TITANIUMALLOY:3||glass forming ability:3||NB:3||kappacarbide:3||CORROSION:3||TI48AL2CR:3||INTERNAL VARIABLE APPROACH:3||crystallization:3||BULK AMORPHOUSALLOYS:3||THERMODYNAMICS:3||bulk amorphous materials:3||casting:3||STEELS:3||GRAINGROWTH:3||superplasticity:3||STRIP:3||Mechanical properties:3||Twinning:3||Ductility:3||BULK METALLICGLASS:3||MODEL:3||PRECIPITATION:3||toughness:3||RECRYSTALLIZATION:3||WELDS:3||creep resistance:3||steel:3||METHOD INTERATOMIC POTENTIALS:3||TEXTURE:3||Rolling:3||TWIP steel:3||mechanical property:3||squeeze casting:3||twinroll strip casting:3||MECHANISMS:3||magnesium alloy:3||VSI ALLOY:3||acicular ferrite:3||CRACKGROWTH:3||fatigue crack growth:3||Twinroll casting:3||mechanical properties:3||MG ALLOYS:3||twinroll casting:3||Formability:3||THERMALSTABILITY:3||oxides:3||intermetallic:3||Strain hardening:3||heterogeneous nucleation:3||TENSILE:3||CASTING METHOD:3||dispersoid particles:3||STRESS:3||yield ratio:3||primary TiB:2||ANNEALED TI6AL4V:2||eutectic silicon particle:2||VARIABLES:2||electron beam irradiation:2||secondary hardening:2||alloy:2||Metallic Materials:2||Cube texture:2||GRAINBOUNDARY SEGREGATION:2||SOLUTE SEGREGATION:2||LOWDENSITY:2||PIPELINE STEEL:2||MO:2||Amorphous matrix composite:2||Straininduced phase transformation:2||Martensitic transformation:2||Charpy Vnotch impact test:2||powder injection molding:2||CU ALLOY:2||plasticity:2||ALUMINATITANIA COATINGS:2||cooling rate:2||dynamic torsional test:2||FERROUS COATINGS:2||CERAMICS:2||crystalline particle:2||titanium castings:2||flux:2||ZR SYSTEM:2||glasses:2||Plasticity:2||Strain rate:2||Thin Films:2||MGZN:2||AUSTENITIC STEEL:2||Monte Carlo simulation:2||Modified embeddedatom method:2||Annealing:2||welding:2||Complex oxides:2||Charpy impact properties:2||Cooling rate:2||ALLOYING ELEMENTS:2||SULFUR:2||aluminumlithium alloys:2||ELECTRONBEAM IRRADIATION:2||drop weight tear test:2||bulk metallic glass:2||AMORPHOUS ALLOY:2||ZN ALLOY:2||Stainless steel:2||FATIGUE:2||MECHANICALBEHAVIOR:2||dispersoid:2||TRANSITION:2||FAILURE:2||MICROSTRUCTURAL REFINEMENT:2||TIG weld:2||tempering:2||hardness:2||PHASETRANSITION:2||AUTOMOTIVE INDUSTRY:2||TRIP:2||AZ31 MAGNESIUM ALLOY:2||WELD:2||Metals:2||Scanning electron microscopy (SEM):2||tensile test:2||metals welding:2||DWTT:2||continuous recrystallization:2||titanium aluminide:2||bulk amorphous matrix composite:2||MICROSTRUCTURAL DEVELOPMENT:2||CREEP:2||ECAP:2||CPSP:2||ALUMINA:2||phase diagram:2||alloy design:2||FORMING ABILITY:2||PARTICLES:2||MgSn alloy:2||Rcurve analysis:2||DYNAMIC RECRYSTALLIZATION:2||thermal barrier coating:2||GLASS:2||hightemperature hardness:2||CRACKGROWTHBEHAVIOR:2||tensile strength:2||Structural Materials:2||0 0 1 >:2||STRUCTURAL STABILITY:2||Transformation induced plasticity (TRIP):2||impact test:2||Dendrite:2||Carbon equivalent:2||DEPOSITION:2||EMBRITTLEMENT:2||SLIP:2||SIMULATION:2||powderinjection molding:2||ABRASIVE WEAR:2||STRUCTURAL SUPERPLASTICITY:2||MNCD:2||free volume:2||Al2O3TiO2 nanopowder:2||SURFACE:2||METALLIC GLASSES:2||MAGNETICPROPERTIES:2||charpy impact test:2||GRAINSIZE:2||ductile crystalline particle:
