|
nanoindentation |
19 |
|
biomechanics |
12 |
|
materials testing |
11 |
|
mechanical properties |
10 |
|
adhesion |
9 |
|
collagen fibril |
9 |
|
interface |
8 |
|
atomic force microscope |
7 |
|
atomic force microscopy |
7 |
|
humans |
7 |
|
adolescent |
6 |
|
bioactive bone cement |
6 |
|
bioactivity |
6 |
|
bone and bones - physiology |
6 |
|
bone cements - metabolism |
6 |
|
cornea |
6 |
|
corrosion resistance |
6 |
|
disc degeneration |
6 |
|
durapatite - metabolism |
6 |
|
elastic modulus |
6 |
|
elasticity |
6 |
|
fibrillar collagens - chemistry - ultrastructure |
6 |
|
fibrosis |
6 |
|
fracture mechanics |
6 |
|
glaucoma |
6 |
|
human intervertebral disc |
6 |
|
implant stability |
6 |
|
intervertebral disk - chemistry |
6 |
|
matrix metalloproteinase 12 |
6 |
|
mesenchymal stem cells/multipotent stromal cells |
6 |
|
microscopy, electron, scanning |
6 |
|
nanofibers - chemistry - ultrastructure |
6 |
|
nanostructure |
6 |
|
nickel titanium |
6 |
|
niti |
6 |
|
nucleus pulposus |
6 |
|
plasma immersion ion implantation |
6 |
|
strontium-containing hydroxyapatite |
6 |
|
trabecular bone |
6 |
|
weight-bearing |
6 |
|
animals |
5 |
|
articular cartilage |
5 |
|
bone and bones - cytology - drug effects - physiology |
5 |
|
bone cements - chemistry - therapeutic use - toxicity |
5 |
|
chromium alloys |
5 |
|
cp: cancer |
5 |
|
cp: metabolism |
5 |
|
durapatite - chemistry - therapeutic use |
5 |
|
finger joint - surgery |
5 |
|
glycolysis |
5 |
|
high-entropy alloys |
5 |
|
hip - physiology |
5 |
|
hip injuries - drug therapy |
5 |
|
lipogenesis |
5 |
|
mechanical property |
5 |
|
mechanotransduction |
5 |
|
metabolic reprogramming |
5 |
|
osseointegration |
5 |
|
ovarian cancer |
5 |
|
p-cadherin |
5 |
|
peritoneal metastasis |
5 |
|
polymethyl methacrylate - toxicity |
5 |
|
prostheses and implants |
5 |
|
rabbits |
5 |
|
stiffness |
5 |
|
total hip arthroplasty |
5 |
|
tumor mesothelium |
5 |
|
artificial joints -- design and construction. |
4 |
|
dislocation |
4 |
|
dislocation dynamics |
4 |
|
dislocations |
4 |
|
finger joint -- data processing. |
4 |
|
microspheres |
4 |
|
microstructure |
4 |
|
reverse engineering. |
4 |
|
yield strength |
4 |
|
actuators |
3 |
|
afm indentation |
3 |
|
anodic aluminium oxide |
3 |
|
anodic aluminum oxide |
3 |
|
biomechanics - methods |
3 |
|
cell differentiation - drug effects |
3 |
|
cell-matrix adhesions |
3 |
|
cell-to-cell contact |
3 |
|
chondrogenesis - drug effects |
3 |
|
collagen - chemistry |
3 |
|
collagen - pharmacology |
3 |
|
collagen microsphere |
3 |
|
cracks |
3 |
|
creep |
3 |
|
crystal plasticity |
3 |
|
deformation |
3 |
|
drug carriers - chemistry |
3 |
|
engineering |
3 |
|
engineering mechanics and materials medical sciences |
3 |
|
fibronectin |
3 |
|
focused-ion-beam |
3 |
|
frequency |
3 |
|
grain boundary |
3 |
|
growth from vapor |
3 |
|
hardness |
3 |
|
hardness testing |
3 |
|
hardness tests - instrumentation - methods |
3 |
|
high entropy alloys |
3 |
|
high-entropy alloy |
3 |
|
hydrogels - chemistry |
3 |
|
leukemia |
3 |
|
materials testing - instrumentation - methods |
3 |
|
materials testing - methods |
3 |
|
maturation |
3 |
|
mechanical force |
3 |
|
mesenchymal stem cells |
3 |
|
mesenchymal stem cells - cytology - drug effects - metabolism - ultrastructure |
3 |
|
metallic zn |
3 |
|
mice |
3 |
|
mice, inbred c57bl |
3 |
|
mice, inbred icr |
3 |
|
micro-pillars |
3 |
|
micromanipulation - methods |
3 |
|
microplate |
3 |
|
migration |
3 |
|
multiphoton biofabrication |
3 |
|
nanomaterials |
3 |
|
nanostructures |
3 |
|
nanotechnology - methods |
3 |
|
necrotic cell death |
3 |
|
optical trap |
3 |
|
optical trapping |
3 |
|
plastic deformation |
3 |
|
protein micropattern |
3 |
|
protein micropillar matrix |
3 |
|
statistical mechanics |
3 |
|
stress, mechanical |
3 |
|
traction-force microscopy |
3 |
|
viscoelastic |
3 |
|
viscosity |
3 |
|
a. intermetallics |
2 |
|
acid concentrations |
2 |
|
activation energy |
2 |
|
activation volume |
2 |
|
additive manufacturing |
2 |
|
ahss |
2 |
|
angular orientation |
2 |
|
animal |
2 |
|
anodic electrodeposition |
2 |
|
anodic porous alumina |
2 |
|
anodizations |
2 |
|
antigen-antibody complex - chemistry |
2 |
|
artificial muscles |
2 |
|
b. phase transformations |
2 |
|
biomineralization |
2 |
|
bovine |
2 |
|
bulk metallic glass (bmg) |
2 |
|
calcification, physiologic |
2 |
|
cell line |
2 |
|
cell mechanics |
2 |
|
cold rolling |
2 |
|
columns |
2 |
|
compression |
2 |
|
d. defects: dislocation geometry and arrangement |
2 |
|
deformation twinning |
2 |
|
dental enamel - chemistry |
2 |
|
dental enamel - pathology - ultrastructure |
2 |
|
dental enamel - physiology |
2 |
|
dental enamel hypoplasia - pathology |
2 |
|
dentin - chemistry |
2 |
|
dentine-enamel junction |
2 |
|
diamond tip |
2 |
|
dislocation resistance |
2 |
|
dynamic strain aging |
2 |
|
electrochemical actuators |
2 |
|
electrolytes |
2 |
|
enamel |
2 |
|
engineering mechanics and materials physics |
2 |
|
extended dislocations |
2 |
|
extrinsic stacking fault |
2 |
|
fcc |
2 |
|
fe3ge |
2 |
|
finite-element modelling |
2 |
|
friction coefficients |
2 |
|
grain and twin boundaries |
2 |
|
grain boundaries |
2 |
|
grain orientation |
2 |
|
hcp |
2 |
|
hepatitis b antibodies - chemistry - immunology |
2 |
|
hepatitis b surface antigens - chemistry - immunology |
2 |
|
heterogeneous atomic environments |
2 |
|
high ductility |
2 |
|
high toughness |
2 |
|
higher temperatures |
2 |
|
honeycombs |
2 |
|
hypomineralization |
2 |
|
incisor - pathology |
2 |
|
indentation |
2 |
|
indentation size effect |
2 |
|
interfaces |
2 |
|
interstitial-free steel |
2 |
|
ise |
2 |
|
laser directed energy deposition |
2 |
|
laser energy density |
2 |
|
leukemia cells |
2 |
|
linear scaling |
2 |
|
load dependence |
2 |
|
local chemical ordering |
2 |
|
local pinning effects |
2 |
|
low voltages |
2 |
|
machine learning |
2 |
|
martensitic transformation |
2 |
|
matrix phase |
2 |
|
mechanical processes |
2 |
|
mechanical property evaluation |
2 |
|
mechanical twins |
2 |
|
medium-mn |
2 |
|
mesoscale plasticity simulation |
2 |
|
metals |
2 |
|
metastasis |
2 |
|
microband |
2 |
|
miscellaneous |
2 |
|
modeling of strengthening |
2 |
|
modulus |
2 |
|
molar - anatomy and histology - physiology |
2 |
|
molar - pathology |
2 |
|
multistimuli-driven actuators |
2 |
|
multistimuli-responsive-sensors |
2 |
|
nanomechanical testing |
2 |
|
nanoscale |
2 |
|
nanostructures - chemistry |
2 |
|
nanotechnology |
2 |
|
nickel hydroxide/oxyhydroxides |
2 |
|
nucleation and growth |
2 |
|
optical tweezers |
2 |
|
oral cancer cells |
2 |
|
ordered and disordered ni 3al |
2 |
|
ovarian cells |
2 |
|
oxidation |
2 |
|
partial dislocations |
2 |
|
phase transformation |
2 |
|
physics engineering chemistry |
2 |
|
plasticity |
2 |
|
powders, porous materials |
2 |
|
protein binding |
2 |
|
replicas |
2 |
|
robotic hair |
2 |
|
second phase |
2 |
|
selenium |
2 |
|
shear-fault fluctuations |
2 |
|
single austenite grain |
2 |
|
size effect |
2 |
|
slip transfer criteria |
2 |
|
soft robotics |
2 |
|
special atomic motifs |
2 |
|
strain rate |
2 |
|
strength |
2 |
|
subgrains |
2 |
|
submicron |
2 |
|
surface referencing |
2 |
|
surface tension |
2 |
|
tem |
2 |
|
tensile test |
2 |
|
thermal drift |
2 |
|
third-generation |
2 |
|
transmission electron microscope |
2 |
|
transmission electron microscopy |
2 |
|
trip |
2 |
|
turbostratic |
2 |
|
viscoelasticity |
2 |
|
γ′-ni 3al |
2 |
|
(fe,cr)al-10%al2o3 nanocomposite |
1 |
|
3d printing |
1 |
|
a. dislocations |
1 |
|
accumulative roll bonding |
1 |
|
acoustic softening |
1 |
|
acoustoplasticity |
1 |
|
actuator |
1 |
|
age hardening |
1 |
|
air-working |
1 |
|
aisi 304l stainless steel |
1 |
|
all-dislocation density |
1 |
|
alloy |
1 |
|
alloys |
1 |
|
aluminides |
1 |
|
aluminium |
1 |
|
aluminum |
1 |
|
aluminum doping |
1 |
|
amorphous alloy composites (aacs) |
1 |
|
anisotropic mobility |
1 |
|
anisotropy |
1 |
|
atomistic mechanism |
1 |
|
atomistic simulation |
1 |
|
austenitic stainless steel |
1 |
|
b. crystal plasticity |
1 |
|
back stress |
1 |
|
back stress strengthening |
1 |
|
barrier layer thickness |
1 |
|
barrier layers |
1 |
|
bcc crystals |
1 |
|
bcc metals |
1 |
|
bi-crystal |
1 |
|
bilayered actuator |
1 |
|
bimodal grain size distribution |
1 |
|
brass pipework |
1 |
|
brazingflame test |
1 |
|
c. integral transforms |
1 |
|
calcium carbonate |
1 |
|
canonical ensemble |
1 |
|
cells |
1 |
|
cellular materials |
1 |
|
characterizations |
1 |
|
chemical analysis |
1 |
|
cobalt hydroxide |
1 |
|
cobalt oxide |
1 |
|
cobalt oxides/hydroxides |
1 |
|
cocrni medium-entropy alloy |
1 |
|
cold sintering |
1 |
|
columnar to equiaxed transition |
1 |
|
complex stress |
1 |
|
composites |
1 |
|
compression test |
1 |
|
compression tests |
1 |
|
constitutional undercooling |
1 |
|
contact mechanics |
1 |
|
continuity equations |
1 |
|
continuous dislocation dynamics |
1 |
|
continuous dynamic recrystallisation |
1 |
|
convolutional neural networks |
1 |
|
copper |
1 |
|
corrosion |
1 |
|
corrosion inhibition |
1 |
|
coupled effect |
1 |
|
crack tip plasticity |
1 |
|
crconi mea |
1 |
|
cryogenic formability |
1 |
|
crystal plasticity finite-element method |
1 |
|
crystalline materials |
1 |
|
crystalline-amorphous interface |
1 |
|
cu 2o single crystals |
1 |
|
cu2o nanowires |
1 |
|
cuprous oxide |
1 |
|
cytology |
1 |
|
deep cryogenic treatment |
1 |
|
deformation area |
1 |
|
deformation mechanism |
1 |
|
deformation structure |
1 |
|
deformation twining |
1 |
|
densification |
1 |
|
diffusion |
1 |
|
discontinuous dynamic recrystallisation |
1 |
|
dislocation annihilation |
1 |
|
dislocation cell |
1 |
|
dislocation cell type martensite |
1 |
|
dislocation core |
1 |
|
dislocation core width distribution |
1 |
|
dislocation densities |
1 |
|
dislocation density |
1 |
|
dislocation dynamics simulation |
1 |
|
dislocation interactions |
1 |
|
dislocation mechanics |
1 |
|
dislocation microstructures |
1 |
|
dislocation mobility |
1 |
|
dislocation structures |
1 |
|
dislocation theory |
1 |
|
dislocation-density functions |
1 |
|
disordered materials |
1 |
|
doping |
1 |
|
dynamic recrystallization |
1 |
|
dynamic tension |
1 |
|
dynamics |
1 |
|
ebsd |
1 |
|
elastic instability |
1 |
|
elastic moduli |
1 |
|
elastostatics |
1 |
|
electric current treatment |
1 |
|
electrical properties and measurements |
1 |
|
electrochemical actuation |
1 |
|
electrochemical actuator |
1 |
|
electrochemical devices |
1 |
|
electrochemical double layer |
1 |
|
electrochemistry |
1 |
|
electrodeposition |
1 |
|
electron backscattering diffraction |
1 |
|
electron beam selective melting |
1 |
|
electronics cooling |
1 |
|
embossing |
1 |
|
entropy |
1 |
|
eutectic |
1 |
|
extrusion direction |
1 |
|
fans |
1 |
|
fatigue crack |
1 |
|
fatigue failure |
1 |
|
first-yield criteria |
1 |
|
foam materials |
1 |
|
foams |
1 |
|
focused ion beam |
1 |
|
focused ion-beam milling |
1 |
|
focussed ion beam (fib) |
1 |
|
fractal |
1 |
|
fracture |
1 |
|
friction stir welding |
1 |
|
gelatin |
1 |
|
geometrically necessary dislocations |
1 |
|
geometry |
1 |
|
glycerol |
1 |
|
gradient structures |
1 |
|
grain boundary resistance |
1 |
|
grain growth |
1 |
|
grain size |
1 |
|
granular materials |
1 |
|
growth rate |
1 |
|
hall-petch relation |
1 |
|
hardening |
1 |
|
hardness test |
1 |
|
heat treatment |
1 |
|
helium |
1 |
|
heterogeneous grain structure |
1 |
|
heterostructure |
1 |
|
high entropy alloy |
1 |
|
high pressure consolidation |
1 |
|
high temperature tensile properties |
1 |
|
high-density polyethylene |
1 |
|
high-pressure torsion |
1 |
|
high-temperature deformation |
1 |
|
hopg |
1 |
|
hydration |
1 |
|
hydrogen embrittlement |
1 |
|
hydrophobic papers |
1 |
|
in situ transmission electron microscopy (tem) |
1 |
|
incipient plasticity |
1 |
|
independently controlled micro-hinges |
1 |
|
indium |
1 |
|
instability |
1 |
|
intermetallics |
1 |
|
interphase interface |
1 |
|
intrinsic heat treatment |
1 |
|
ion beams |
1 |
|
ion-beam processing |
1 |
|
lamellae |
1 |
|
laser shock peening |
1 |
|
laser-directed energy deposition |
1 |
|
lath type martensite |
1 |
|
lead leaching |
1 |
|
light-induced actuation |
1 |
|
light-induced actuator |
1 |
|
linear elasticity |
1 |
|
local resistive environments |
1 |
|
low light intensity |
1 |
|
low strain rate |
1 |
|
main drive chain |
1 |
|
manganese dioxide |
1 |
|
medium entropy alloys |
1 |
|
meso-scale simulation |
1 |
|
metallic glass |
1 |
|
metallic glass composites (mgcs) |
1 |
|
mg-gd-y-zr alloys |
1 |
|
micro-crystals |
1 |
|
micro-origami robotics |
1 |
|
micro-riveting |
1 |
|
microfiber |
1 |
|
microfibers |
1 |
|
micromechanical modeling |
1 |
|
micropillar |
1 |
|
micropillars |
1 |
|
molecular dynamics |
1 |
|
molecular dynamics (md) simulation |
1 |
|
monte carlo simulation |
1 |
|
monte carlo techniques |
1 |
|
multi-component alloys |
1 |
|
multiscale |
1 |
|
multiscale modeling |
1 |
|
multiscale simulation |
1 |
|
nano-grained metals |
1 |
|
nano-scratch |
1 |
|
nano-twins |
1 |
|
nanocrystalline material |
1 |
|
nanocrystals |
1 |
|
nanohoneycomb nickel |
1 |
|
nanoidentation |
1 |
|
nanoindenation |
1 |
|
nanomechanics |
1 |
|
nanoparticle |
1 |
|
nanoporous materials |
1 |
|
nanoporous metals |
1 |
|
ni/water interface |
1 |
|
nickel aluminides |
1 |
|
nickel hydroxide |
1 |
|
nickel hydroxide-oxyhydroxide |
1 |
|
nickel oxyhydroxide |
1 |
|
nonlocal velocity |
1 |
|
numerical simulation |
1 |
|
octahedral |
1 |
|
open electrodeposition |
1 |
|
paper-based microfluidics |
1 |
|
pb-brass segregation |
1 |
|
peierls stress |
1 |
|
physical metallurgy |
1 |
|
physics |
1 |
|
physics engineering |
1 |
|
planar fault energy distribution |
1 |
|
pma |
1 |
|
point defect |
1 |
|
polycrystalline |
1 |
|
polymers |
1 |
|
precipitate hardening |
1 |
|
precipitation hardening |
1 |
|
precipitation strengthening |
1 |
|
printed robots |
1 |
|
q235 carbon steel |
1 |
|
radiation tolerant materials |
1 |
|
radiation-induced precipitate |
1 |
|
random materials |
1 |
|
random packings |
1 |
|
rate-jump test |
1 |
|
recrystallisation |
1 |
|
recrystallization |
1 |
|
recrystallization mechanism |
1 |
|
residual stress |
1 |
|
resistivity |
1 |
|
reversible redox reactions |
1 |
|
reversion mechanism |
1 |
|
safety factor |
1 |
|
safety regulations |
1 |
|
schmid's law |
1 |
|
scratching test |
1 |
|
seawater |
1 |
|
seawater toilet flushing |
1 |
|
self-organization and patterning |
1 |
|
shear bands |
1 |
|
shear localization |
1 |
|
shear punch testing |
1 |
|
shear strain rate |
1 |
|
shear transformation zones |
1 |
|
shear wave |
1 |
|
sigma phase precipitate |
1 |
|
sigma phase precipitation |
1 |
|
silver |
1 |
|
simulation |
1 |
|
simulations |
1 |
|
single crystal |
1 |
|
single crystals |
1 |
|
sintering |
1 |
|
size effects |
1 |
|
sputtering |
1 |
|
stacking-fault energy |
1 |
|
statistical physics |
1 |
|
stimuli-responsive materials |
1 |
|
stochastic deformation |
1 |
|
strain rate sensitivity |
1 |
|
strain-gradient plasticity |
1 |
|
stress-strain behavior |
1 |
|
stress-strain relation |
1 |
|
subgrain formation |
1 |
|
super-long escalators |
1 |
|
superplasticity |
1 |
|
surface stress |
1 |
|
surface-charge-induced strain |
1 |
|
tensile properties |
1 |
|
tensile testing |
1 |
|
textural evolution |
1 |
|
texture |
1 |
|
thermal desorption |
1 |
|
thermally activated processes |
1 |
|
thermocalc |
1 |
|
thermomechanical processing |
1 |
|
threshold dynamics method |
1 |
|
tial3 |
1 |
|
tialv alloy |
1 |
|
titanium alloys |
1 |
|
tme |
1 |
|
tongue squamous cell carcinoma |
1 |
|
transition metal oxide |
1 |
|
transition-metal oxides/hydroxides |
1 |
|
triple junction |
1 |
|
tunable stiffness |
1 |
|
turbostratic structures |
1 |
|
twinning |
1 |
|
two-sphere model |
1 |
|
ultrafine grain |
1 |
|
ultrasonic softening |
1 |
|
ultrasonics |
1 |
|
variable stretching |
1 |
|
vimentin |
1 |
|
visible-light-induced actuation |
1 |
|
visible‐light actuation |
1 |
|
water intercalation |
1 |
|
water-induced actuators |
1 |
|
whiskers |
1 |
|
work hardening |
1 |
|
yield phenomena |
1 |
|
yield stress |
1 |
|
young's modulus |
1 |
|
zener-hollomon parameter |
1 |
