|
martensitic transformation |
6 |
|
medium mn steel |
5 |
|
q&p steel |
5 |
|
stacking fault energy |
5 |
|
dislocation density |
4 |
|
ductility |
4 |
|
trip |
4 |
|
trip effect |
4 |
|
austenite stability |
3 |
|
chemical compositions |
3 |
|
deformation twinning |
3 |
|
density functional theory |
3 |
|
heterogeneous structure |
3 |
|
lüders band |
3 |
|
machine learning |
3 |
|
mechanical properties |
3 |
|
mechanical twins |
3 |
|
medium-mn |
3 |
|
mg alloys |
3 |
|
rare earth |
3 |
|
thermodynamics |
3 |
|
twinning |
3 |
|
twip steel |
3 |
|
warm rolling |
3 |
|
ahss |
2 |
|
austenite |
2 |
|
austenite grain |
2 |
|
austenite volume fraction |
2 |
|
austenitic steels |
2 |
|
bainite |
2 |
|
band convergence |
2 |
|
chemical composition |
2 |
|
deformation induced martensitic transformation |
2 |
|
dislocation |
2 |
|
dislocation engineering |
2 |
|
dislocation multiplication |
2 |
|
dislocation plasticity |
2 |
|
fracture toughness |
2 |
|
high strain rate |
2 |
|
high temperature |
2 |
|
hopkinson tensile bar |
2 |
|
hydrogen embrittlement |
2 |
|
intercritical annealing |
2 |
|
interfacial shear strength |
2 |
|
lattice dislocations |
2 |
|
lattice thermal conductivity |
2 |
|
lüders strain |
2 |
|
lüders-strain-rate |
2 |
|
mechanically induced martensitic transformation |
2 |
|
medium mn steels |
2 |
|
micro-dic |
2 |
|
model |
2 |
|
nanoindentation |
2 |
|
nucleation and growth |
2 |
|
partial dislocations |
2 |
|
phase transformation |
2 |
|
prior austenite grain size |
2 |
|
quenching and partitioning |
2 |
|
quenching and partitioning steel |
2 |
|
retained austenite |
2 |
|
single austenite grain |
2 |
|
stabilization mechanisms |
2 |
|
strain rate |
2 |
|
strain-rate sensitivity |
2 |
|
strength and ductility |
2 |
|
stress assisted transformation |
2 |
|
submicron |
2 |
|
synchrotron x-ray diffraction |
2 |
|
temperature quenching |
2 |
|
thermoelectrics |
2 |
|
third-generation |
2 |
|
twip steels |
2 |
|
welding |
2 |
|
work hardening |
2 |
|
yield ratio |
2 |
|
316l stainless steel |
1 |
|
3d printing |
1 |
|
a. intermetallics, miscellaneous |
1 |
|
a. phase transformation |
1 |
|
a. twinning |
1 |
|
abnormal hall-petch |
1 |
|
advanced high strength steels |
1 |
|
age hardening |
1 |
|
al-alloyed steel |
1 |
|
alsi coating |
1 |
|
aluminum |
1 |
|
anti-corrosion |
1 |
|
antibacterial mechanism |
1 |
|
ausforming |
1 |
|
austenitic steel |
1 |
|
austenitization temperature |
1 |
|
auto-tempering |
1 |
|
axial tensions |
1 |
|
b. metallic material |
1 |
|
b. yield stress |
1 |
|
bainites |
1 |
|
bainitic steels |
1 |
|
bainitic transformation |
1 |
|
ballistic impact |
1 |
|
batch annealing |
1 |
|
bcc hea |
1 |
|
bendability |
1 |
|
beta titanium alloy |
1 |
|
biaxial loading |
1 |
|
biomedical titanium alloy |
1 |
|
blunt crack |
1 |
|
boron |
1 |
|
boron segregation |
1 |
|
boundary dislocation enrichment |
1 |
|
brittle |
1 |
|
c. reaction synthesis |
1 |
|
carbide-free bainite |
1 |
|
carbon |
1 |
|
carbon content |
1 |
|
carbon distribution |
1 |
|
carbon-dislocation interaction |
1 |
|
change in microstructures |
1 |
|
charpy impact energy |
1 |
|
chemical structure |
1 |
|
cleavage |
1 |
|
coble creep |
1 |
|
cohesive zone model |
1 |
|
cohesive zone models |
1 |
|
complex concentrated alloy |
1 |
|
compositional effects |
1 |
|
compositionally complex alloy |
1 |
|
compositionally complex oxide |
1 |
|
concentration (parameter) |
1 |
|
constitutive relations |
1 |
|
continuous transformations |
1 |
|
corrosion |
1 |
|
corrosion-resistant |
1 |
|
corrosive environment |
1 |
|
cottrell atmosphere |
1 |
|
coupled thermo-mechanical analysis |
1 |
|
cr-depletion |
1 |
|
crack closure |
1 |
|
crack initiation energy |
1 |
|
crash performance |
1 |
|
critical resolved shear stress |
1 |
|
critical strains |
1 |
|
cross slip |
1 |
|
crystal orientation |
1 |
|
crystal plasticity models |
1 |
|
crystallographic anisotropy |
1 |
|
crystallography |
1 |
|
d&p steel |
1 |
|
d. phase interfaces |
1 |
|
damage tolerance |
1 |
|
dbtt |
1 |
|
deep-drawn cups |
1 |
|
defects |
1 |
|
deformation |
1 |
|
deformation band |
1 |
|
deformation behaviour |
1 |
|
deformation mechanism |
1 |
|
deformation twin |
1 |
|
delamination |
1 |
|
delayed fracture |
1 |
|
density |
1 |
|
dic |
1 |
|
differential equations |
1 |
|
digital image correlation |
1 |
|
dipole emission |
1 |
|
dislocation activity |
1 |
|
dislocation annihilation |
1 |
|
dislocation cell |
1 |
|
dislocation climb |
1 |
|
dislocation emission |
1 |
|
dislocation evolution |
1 |
|
dislocation interaction |
1 |
|
dislocation mobility |
1 |
|
dislocation substructure |
1 |
|
dislocations |
1 |
|
dp |
1 |
|
dp steel |
1 |
|
drawn cups |
1 |
|
dual-phase heterogeneous structure |
1 |
|
dual-phase mediums |
1 |
|
ductile |
1 |
|
ductile fracture |
1 |
|
dynamic recovery |
1 |
|
dynamic recrystallization |
1 |
|
dynamic strain aging |
1 |
|
dynamic stress/strain |
1 |
|
electrodiffusion model |
1 |
|
electron backscattering diffraction (ebsd) |
1 |
|
element diffusion and segregation |
1 |
|
energy dissipation |
1 |
|
energy release rate |
1 |
|
entropy |
1 |
|
eutectic particle cluster |
1 |
|
experimental validations |
1 |
|
exposed to |
1 |
|
face-centered-cubic (fcc) metals |
1 |
|
fatigue |
1 |
|
fatigue crack growth |
1 |
|
fatigue crack initiation |
1 |
|
fatigue crack propagation |
1 |
|
fatigue resistance |
1 |
|
feg-sem |
1 |
|
ferrite transformation |
1 |
|
ferrite/martensite interface decohesion |
1 |
|
ferrites |
1 |
|
fine martensite lath |
1 |
|
finite element method |
1 |
|
first generation ahss |
1 |
|
first-principles calculations |
1 |
|
flow stress |
1 |
|
fracture |
1 |
|
fracture behavior |
1 |
|
fracture behaviour |
1 |
|
fracture mechanism |
1 |
|
fretting wear |
1 |
|
g. thermoelectric power generation |
1 |
|
gnd |
1 |
|
grain boundary |
1 |
|
grain boundary diffusion |
1 |
|
grain boundary dynamic recovery |
1 |
|
grain boundary segregation |
1 |
|
grain refinement |
1 |
|
grain size |
1 |
|
grain size dependence |
1 |
|
heat input energy |
1 |
|
heavy-metal ions |
1 |
|
helium ion microscope |
1 |
|
helium irradiation blistering |
1 |
|
hetero-deformation induced strengthening |
1 |
|
high cycle fatigue |
1 |
|
high strain rate deformation |
1 |
|
high strength steel |
1 |
|
high strength steels |
1 |
|
high temperature deformation |
1 |
|
high throughput |
1 |
|
high-entropy alloy |
1 |
|
high-modulus steel |
1 |
|
high-modulus steels |
1 |
|
high-pressure torsion |
1 |
|
high-strain-rate deformation |
1 |
|
hot deformation |
1 |
|
hot rolling |
1 |
|
hot stamping |
1 |
|
hydrogen risk predictions |
1 |
|
hydrophilic pore |
1 |
|
if steels |
1 |
|
inclusion engineering |
1 |
|
induced transformation |
1 |
|
industrial alloys |
1 |
|
interbubble fracture |
1 |
|
interdiffusion ferrite |
1 |
|
interface strength |
1 |
|
interfacial plasticity |
1 |
|
interfacial strength |
1 |
|
interrupted tensile test |
1 |
|
interstitials |
1 |
|
ion channeling effects |
1 |
|
irreversible thermodynamics |
1 |
|
its efficiencies |
1 |
|
kinematic hardening |
1 |
|
kinetics |
1 |
|
lath martensite |
1 |
|
lath misorientation |
1 |
|
lath size |
1 |
|
lath thickness |
1 |
|
lightweight materials |
1 |
|
lightweight steel |
1 |
|
long-period stacking ordered (lpso) phase |
1 |
|
low temperature deformations |
1 |
|
low temperatures |
1 |
|
low-activation |
1 |
|
low-density steels |
1 |
|
magnesium alloys |
1 |
|
martensite |
1 |
|
martensite volume fraction |
1 |
|
martensites |
1 |
|
mechanical performance |
1 |
|
mechanical property |
1 |
|
medium mn trip steel |
1 |
|
medium-mn steel |
1 |
|
medium-mn steels |
1 |
|
micro-pillar |
1 |
|
micro-structure evolutions |
1 |
|
microalloying |
1 |
|
micromechanical tensile test |
1 |
|
micropillar |
1 |
|
micropillar compression |
1 |
|
micropillars |
1 |
|
microscopic oxidation mechanism |
1 |
|
microstructure |
1 |
|
microstructure evolution |
1 |
|
mn trip steel |
1 |
|
mode i |
1 |
|
mode i and mode ii crack |
1 |
|
mode ii |
1 |
|
modelling |
1 |
|
molecular dynamics simulations |
1 |
|
morphology |
1 |
|
morphology effect |
1 |
|
ms temperature |
1 |
|
multi-phase medium |
1 |
|
multiphase microstructure |
1 |
|
nano-cavity |
1 |
|
nano-indentation |
1 |
|
nanocrystalline |
1 |
|
nanohardness |
1 |
|
nanoparticle |
1 |
|
nanostructure |
1 |
|
nanostructures |
1 |
|
nanotwin |
1 |
|
neutral environment |
1 |
|
ni-based alloy |
1 |
|
non-equilibrium thermodynamics |
1 |
|
nucleation mechanism |
1 |
|
orientation |
1 |
|
osmotic pressure |
1 |
|
oxidation behavior |
1 |
|
oxidation-resistant mg alloys |
1 |
|
partial dislocation |
1 |
|
partial recrystallization |
1 |
|
phase transformations |
1 |
|
physical model |
1 |
|
pillar |
1 |
|
plasma-facing tungsten |
1 |
|
plastic deformation |
1 |
|
polycrystalline |
1 |
|
porous materials |
1 |
|
precipitates |
1 |
|
precipitation strengthening |
1 |
|
press-hardened steel |
1 |
|
press-hardened steels |
1 |
|
primary creep |
1 |
|
processing |
1 |
|
qp steels |
1 |
|
quasi-cleavage |
1 |
|
quasi-cleavage fracture |
1 |
|
quasi-static strain rates |
1 |
|
quenching process |
1 |
|
quenching temperature |
1 |
|
radiation |
1 |
|
radiation blistering |
1 |
|
recovery |
1 |
|
recrystallization |
1 |
|
residual stresses patterns |
1 |
|
room-temperature quenching and partitioning |
1 |
|
saturation stress |
1 |
|
sequential dual-passivation |
1 |
|
severe plastic deformation |
1 |
|
shearable precipitate |
1 |
|
silicon |
1 |
|
single crystals |
1 |
|
size effect |
1 |
|
slow strain rate tests |
1 |
|
smc |
1 |
|
solid solution |
1 |
|
spinel structure |
1 |
|
spinodal decomposition |
1 |
|
stainless steel |
1 |
|
static recrystallisation |
1 |
|
statistical mechanics |
1 |
|
steady state deformation |
1 |
|
steady state stress |
1 |
|
steel |
1 |
|
steel matrix composite |
1 |
|
steel-matrix composites |
1 |
|
steels |
1 |
|
strain burst |
1 |
|
strain partitioning |
1 |
|
strain rate sensitivity |
1 |
|
strain-hardening |
1 |
|
strength |
1 |
|
strengthening |
1 |
|
strengthening mechanism |
1 |
|
strength–ductility synergy |
1 |
|
stress relaxation |
1 |
|
stress-strain modelling |
1 |
|
structure integrity |
1 |
|
subgrain size |
1 |
|
subgrains |
1 |
|
superelasticity |
1 |
|
synchrotron xrd |
1 |
|
taylor factor |
1 |
|
tem |
1 |
|
tempered bainite |
1 |
|
tensile ductility |
1 |
|
test methods |
1 |
|
thermal effects |
1 |
|
thermal mechanical simulation |
1 |
|
thermally activated processes |
1 |
|
thermostatistics |
1 |
|
third generation ahss |
1 |
|
ti alloy |
1 |
|
tip radius |
1 |
|
titanium |
1 |
|
transformation induced plasticity |
1 |
|
transmembrane potential |
1 |
|
tungsten |
1 |
|
twin |
1 |
|
twin boundary |
1 |
|
twin volume fraction |
1 |
|
twinning induced plasticity |
1 |
|
twinning kinetics |
1 |
|
twinning-induced plasticity steel |
1 |
|
twip |
1 |
|
ultra-fine grain |
1 |
|
ultra-high strength |
1 |
|
ultra-high strength dp steel |
1 |
|
ultra-low carbon bainitic steels |
1 |
|
ultrafine grain size |
1 |
|
ultrafine grained alloys |
1 |
|
ultrafine-grained |
1 |
|
ultrafine-grained structure |
1 |
|
ultrahigh strength |
1 |
|
ultrahigh strength steel |
1 |
|
vanadium |
1 |
|
vanadium carbides |
1 |
|
water electrolysis |
1 |
|
work hardening modelling |
1 |
|
work-hardening |
1 |
|
yield point elongation |
1 |
|
yield point phenomenon |
1 |
|
yield stress |
1 |
|
ε-carbide |
1 |
