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KOO, YANG MO (구양모)
Graduate Institute of Ferrous Technology(철강대학원)
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ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magnetic properties:2||MICROALLOYED STEELS:2||SLABS:2||SPIN:2||hot ductility:2||FILM LAYERED STRUCTURES:2||grain refinement:2||THINFILMS:2||THERMODYNAMIC ASSESSMENT:2||COPT:2||microdiffraction:2||B2TIFE 001:2||NITI:2||ELECTRONICSTRUCTURE:2||Aluminum:2||Ferroelectricity:2||PEROVSKITES:2||MN ALLOYS:2||surface hardening:2||single crystal:2||electron beam:2||surface alloying:2||TITANIUM:2||Silicon steel:2||Selective local spin reversal:2||LU:2||MECHANISM:2||plain carbon steel:2||IMPURITIES:2||HYDRIDE:2||NONEQUILIBRIUM SEGREGATION:2||ab initio calculations:2||Texture:2||PT/CO MULTILAYERS:2||SUPERLATTICES:2||thermal simulation:2||L1(0) FEPT:2||ORDERED PHASES:2||STATES:2||NIAL(110):2||RHODIUM:2||OPTICALPROPERTIES:2||SEGREGATION:2||Electrical steels:2||DEFORMATION TEXTURES:2||SYSTEM:2||POLARIZATION:2||CRYSTALSTRUCTURE:2||NITI MARTENSITE:2||DEFORMATION:2||martensitic transformation:2||dilatometer:2||IRON TITANIUM DEUTERIDE:2||hightemperature hardness:2||EMBRITTLEMENT:2||Recrystallization:2||Improper ferroelectricity:2||RAREEARTH ORTHOFERRITES:2||Boron:2||XRAYDIFFRACTION:2||SAPPHIRE:2||SIMULATION:2||tensile axis rotation:2||polycrystal:2||Electrical steel:1||Twin boundary:1||GRAINORIENTATION:1||TWINNINGINDUCED PLASTICITY:1||PROFILE ANALYSIS:1||TWIP STEELS:1||CONTRAST:1||Nonequilibrium Grain Boundary Segregation:1||IFSTEEL:1||molecular field theory:1||LIMN2O4 NANORODS:1||Electron backscatter diffraction:1||ELECTROCHEMICAL PERFORMANCE:1||interfacial mixing:1||COERCIVITY:1||texture:1||transformation into ordered phase:1||UNDERLAYER:1||ANISOTROPY:1||KINETICS:1||LIQUID:1||Schmid factor:1||KirkpatrickBaez mirrors:1||independent adjustability:1||glide strain:1||SURFACEENERGY:1||Alfree:1||Universal binding energy curve:1||SILICON:1||DECOMPOSITION:1||Neutron diffraction:1||STACKINGFAULT ENERGY:1||CUBICCRYSTALS:1||STACKING:1||Effective Time Method:1||BCC METALS:1||NB:1||synchrotron radiation:1||ELECTROCHEMICAL PROPERTIES:1||PERFORMANCE:1||thermal cycle:1||Cr2N age precipitation:1||sensitivity analysis:1||TITANIUMALLOYS:1||STRUCTURALCHARACTERIZATION:1||INTERCALATION:1||boron bearing steel:1||CIRCULARDICHROISM:1||Lshaped mirror holder:1||OXIDATION:1||Electromagnetic induction:1||Average grain size:1||Grain size:1||MULTICOMPONENT ALLOYS:1||DIFFUSION:1||Nonequilibrium segregation:1||High manganese steels:1||C ALLOYS:1||LINE:1||FAULTS:1||SHEETS:1||Hot ductility:1||elastic anisotropy:1||GID (grazing incidence Xray diffraction):1||MANGANESE OXIDE:1||nitride:1||MANGANESE OXIDE NANOCOMPOSITE:1||TENSILESTRENGTH:1||PREDICTION:1||polarized EXAFS:1||Co/Pd multilayer:1||MN SINGLECRYSTALS:1||strain by phase transformation:1||vookwitt condition:1||SEXAFS:1||NI:1||amorphization:1||microXAFS:1||hard Xray:1||beamline:1||GRAINBOUNDARY MOTION:1||Grain size and shape:1||Manganese:1||Austenitetoferrite transformation:1||PRECIPITATION BEHAVIOR:1||Twinning:1||REFINEMENT:1||MODEL:1||Particle Tracking Autoradiography:1||Copperbearing bake hardening steel:1||Twostep rolling annealing process:1||EVOLUTION:1||AL STEELS:1||SILICON STEEL SHEETS:1||TRANSFORMATION TEXTURE:1||CONSTANTS:1||ultra trace element quantitative analysis:1||ALLOYFILMS:1||MAGNETOOPTICAL RECORDING MATERIALS:1||AlN thin film:1||NANOWIRES:1||CRYSTALLIZATION PROCESS:1||POLY(ETHYLENE2,6NAPHTHALATE):1||DISCONTINUOUS PRECIPITATION:1||depth profile:1||thermal analysis:1||metallic glass:1||spherical joint:1||spectroscopy:1||Eddy currentloss:1||AUSTENITIC STAINLESSSTEEL:1||Strainenergyreleasemaximization model:1||Highstrength steel:1||TRIP/TWIP STEELS:1||Grain growth:1||phase transformation:1||cubeonface texture:1||CARBON:1||TXRF:1||phase diagram:1||Al2O3 substrate:1||orientational relationship:1||Centraltunneled morphology:1||Rate capability:1||NANOMATERIALS:1||N content:1||ANODICOXIDATION:1||MNO2 NANOSHEETS:1||ANILINE:1||TI6AL4V ALLOY:1||perpendicular magnetic anisotropy:1||CO/CU MULTILAYERS:1||FePt:1||GRAININTERACTION:1||local deformation:1||amorphous materials:1||FERROMAGNETS:1||6 DOF mirror manipulator:1||SILICONIRON:1||Magnetic cores:1||Magnetic domains:1||Core loss:1||Deformation twin:1||ENHANCEMENT:1||TWIP:1||VOIGTFUNCTION:1||MECHANISMS:1||magnetic properties:1||FeC system:1||HYSTERESIS:1||line profile analysis:1||Rolling:1||Copper:1||BN precipitation:1||PLASTICALLY DEFORMEDCRYSTALS:1||liquid quenching:1||Xray spectroscopy:1||channelcut crystal monochromator:1||TEXTURE:1||Magnetic flux:1||Al composition:1||High resistivity:1||Loss separation:1||Nonoriented electrical steel:1||IRONCARBON ALLOYS:1||NITROGEN:1||Surface energy scaling:1||FCC:1||Cube texture:1||High Mn steel:1||Hardenability:1||HARDENABILITY:1||MO:1||HADFIELD STEEL:1||Neutron scattering:1||Enhancement of gamma fiber:1||Surface crack:1||DEFORMEDCRYSTALS:1||Synchrotron powder Xray diffraction:1||CATHODE MATERIALS:1||Boronbearing steel:1||POLYMERIZATION:1||BN:1||cooling rate:1||anisotropic strain:1||magnetoelastic anisotropy:1||TENSION:1||synchrotron radiationtotal reflection Xray fluorescence (SRTXRF):1||EXAFS:1||NEXAFS:1||GLASSFORMATION:1||containerless processing:1||superconducting wiggler:1||Xray diffraction (XRD):1||Magnetism:1||Annealing textures:1||Goss textures:1||PHASEFIELD MODEL:1||Molecular dynamics simulation:1||Goss texture:1||EBSD:1||GRAIN:1||Continuous cast slab:1||Precipitation:1||Boronnitride:1||Titaniumnitride:1||ELASTIC PROPERTIES:1||high magnetic field:1||DEPENDENCE:1||Nanorod assembled spinel Li1 05Mn1 95O4:1||Rechargeable lithium ion batteries:1||MNO2:1||ALUMINUM:1||neural networks modeling:1||MATERIALS SCIENCE:1||FE FILMS:1||plastic deformation:1||GRAINSTRUCTURE:1||reflection Laue method:1||MIRROR:1||Preannealing:1||Annealing:1||XRAY:1||ALLOYS:8||electronic structure:8||BEHAVIOR:7||IRON:6||MICROSTRUCTURE:5||GRAINBOUNDARY SEGREGATION:5||TRANSFORMATION:5||TRANSVERSE CRACKING:5||alloys:4||optical conductivity:4||ALLOY:4||TiFe:4||transition metal alloys:4||HYDROGEN:4||SURFACES:4||MAGNETISM:4||METALS:4||hydrogen storage alloy:4||GRAINSIZE:4||MAGNETICPROPERTIES:4||LOWCARBON STEELS:4||STRESS:4||TEMPERATURE:4||electronic band structure:4||MN:3||REACTIVITY:3||ELECTRONSTRUCTURE:3||SOLIDIFICATION:3||NANOPARTICLES:3||FILMS:3||PD/CO:3||slip system:3||METALSURFACES:3||OXYGEN:3||PRECIPITATION:3||PHASETRANSITION:3||RECRYSTALLIZATION:3||TIFE:3||GROWTH:3||MOMENT:3||CO:3||Stacking fault energy:3||CRYSTALS:3||surface and interfaces:2||TIO2:2||INTERMETALLIC COMPOUNDS:2||NEUTRONDIFFRACTION:2||SURFACE:2||PALLADIUM:2||copper:2||hydrogen adsorption:2||Ti6A14V:2||boride:2||primary TiB:2||FE:2||Collinear spin ordering:2||Relaxor ferroelectric:2||MECHANICALPROPERTIES:2||orderdisorder transition:2||Si wafer:2||FERRITE:2||CU:2||MEDIA:2||thin films:2||CREEP CAVITATION:2||SULFUR:2||Mtype hexaferrites:2||ELECTRIC POLARIZATION:2||STRENGTH:2||Thin films:2||YMNO3:2||NIMN:2||APPROXIMATION:2||PHASETRANSITIONS:2||phase transitions:2||PERPENDICULAR MAGNETICANISOTROPY:2||corner crack:2||highenergy electron beam:2||ALLELECTRON:2||Magneti
