|
hydrogen storage |
9 |
|
hydrogen storage materials |
6 |
|
carbon |
5 |
|
carbon capture |
4 |
|
catalysis |
4 |
|
density functional theory |
4 |
|
high capacity |
4 |
|
lithium borohydride |
4 |
|
magnesium hydride |
4 |
|
mechanical alloying |
4 |
|
nanoconfinement |
4 |
|
oxygen evolution reaction |
4 |
|
anodic wo3 |
3 |
|
biomass |
3 |
|
carbon dioxide |
3 |
|
co-precipitation |
3 |
|
crystal growth |
3 |
|
electrocatalysis |
3 |
|
electrocatalysts |
3 |
|
etching-induced photoanode |
3 |
|
g-c3n4 |
3 |
|
graphene oxide |
3 |
|
h2o2 photosynthesis |
3 |
|
hydrogen desorption |
3 |
|
hydrogen evolution |
3 |
|
in-situ characterisations |
3 |
|
kinetics |
3 |
|
mechanical milling |
3 |
|
morphology control |
3 |
|
nanostructure |
3 |
|
nanostructures |
3 |
|
nucleation |
3 |
|
photoelectrochemical water splitting |
3 |
|
solution synthesis |
3 |
|
sub-bands |
3 |
|
the growth mechanism of anodization |
3 |
|
transient absorption spectroscopy |
3 |
|
water splitting |
3 |
|
z-scheme |
3 |
|
*oh adspecies |
2 |
|
adipic acid |
2 |
|
alcohol oxidation |
2 |
|
alloying effect |
2 |
|
amylose |
2 |
|
annealing temperature |
2 |
|
biomass material |
2 |
|
chemical properties |
2 |
|
consolidation |
2 |
|
cyclic stability |
2 |
|
d band center |
2 |
|
doping |
2 |
|
electrochemical oxidation |
2 |
|
electrochemical performance |
2 |
|
electrochemistry |
2 |
|
electron synergistic effect |
2 |
|
electronic simulation |
2 |
|
ferrocene |
2 |
|
first-principles calculations |
2 |
|
fuel cells |
2 |
|
furfural hydrogenation |
2 |
|
furfuryl alcohol |
2 |
|
grain size |
2 |
|
graphdiyne |
2 |
|
graphene |
2 |
|
green materials |
2 |
|
high-valence oxides |
2 |
|
hydrogen absorbing materials |
2 |
|
hydrogenation |
2 |
|
interface engineering |
2 |
|
intermetallic compounds |
2 |
|
libh4 |
2 |
|
linh2 |
2 |
|
lithium-ion batteries |
2 |
|
mechanical properties |
2 |
|
mesoporous carbon |
2 |
|
metal hydrides |
2 |
|
metal matrix composites |
2 |
|
metal matrix composites (mmcs) |
2 |
|
metal–organic frameworks |
2 |
|
mg alloys |
2 |
|
mg hydride |
2 |
|
mg-based alloy |
2 |
|
mg2feh6 |
2 |
|
mgh 2 |
2 |
|
milling |
2 |
|
mos 2 |
2 |
|
nano-particles |
2 |
|
nanostructured materials |
2 |
|
oxygen evolution |
2 |
|
oxygen reduction reaction |
2 |
|
phosphorene |
2 |
|
photocatalysis |
2 |
|
pine cone |
2 |
|
plastic upcycling |
2 |
|
porous sio2 nanospheres |
2 |
|
ptcuco alloy |
2 |
|
pt−pd/ni/c |
2 |
|
reversibility catalysis |
2 |
|
semiconductors |
2 |
|
solid-amine |
2 |
|
spinel phases |
2 |
|
strain effect |
2 |
|
sulfur cathode |
2 |
|
synthesis |
2 |
|
thermal conductivity |
2 |
|
ti aluminides |
2 |
|
titanium alloy |
2 |
|
transition metals |
2 |
|
trimetallic catalyst |
2 |
|
ultrahigh pore volumes |
2 |
|
valence tuning |
2 |
|
za alloys |
2 |
|
2d |
1 |
|
2d materials |
1 |
|
3d sandwich arrays |
1 |
|
a. titanium aluminides |
1 |
|
ab initio calculations |
1 |
|
ab initio simulation |
1 |
|
activated carbon |
1 |
|
additional annealing |
1 |
|
additional rolling |
1 |
|
adf-stem |
1 |
|
adsorption |
1 |
|
adsorption capacities |
1 |
|
aerobic oxidation |
1 |
|
aerosol assisted chemical vapour deposition |
1 |
|
aerosol-assisted chemical vapour deposition |
1 |
|
alanate |
1 |
|
alkali treatment |
1 |
|
alkaline electrolyte |
1 |
|
alloy design |
1 |
|
aluminide |
1 |
|
aluminium |
1 |
|
aluminium foil |
1 |
|
amide |
1 |
|
amorphization |
1 |
|
amplitude modulation |
1 |
|
anode materials |
1 |
|
apatite |
1 |
|
as-cast microstructure |
1 |
|
atomic absorption spectrometry |
1 |
|
b. electronic structure of metals and alloys |
1 |
|
ball milling |
1 |
|
band gap scaling law |
1 |
|
band structure |
1 |
|
bandstructure |
1 |
|
barium compounds |
1 |
|
based on tial |
1 |
|
bilayer |
1 |
|
bimetallic cluster |
1 |
|
binder burnout |
1 |
|
biocompatibility |
1 |
|
bioelectricity |
1 |
|
bioelectrochemical system (bes) |
1 |
|
bioinformatics |
1 |
|
biointerface |
1 |
|
biomass valorisation |
1 |
|
biomaterial |
1 |
|
biomaterials |
1 |
|
biomedical application |
1 |
|
biomimetical deposition. |
1 |
|
birefringence |
1 |
|
black hole |
1 |
|
black phosphorene |
1 |
|
black phosphorus |
1 |
|
black phosphorus nanostructures |
1 |
|
bone-like apatite nanocrystal coating |
1 |
|
bulk modulus |
1 |
|
calculation |
1 |
|
capacitive energy storage |
1 |
|
capacitor |
1 |
|
carbon foam |
1 |
|
carbon nanotube films |
1 |
|
carbon storage |
1 |
|
casting |
1 |
|
cathodes |
1 |
|
cellular automata |
1 |
|
cellular automaton |
1 |
|
cellular-automaton |
1 |
|
ceramic |
1 |
|
chemical activity towards co 2 |
1 |
|
cleavage strength |
1 |
|
co oxidation |
1 |
|
co3+-o-v4+ cluster |
1 |
|
co3o4 cocatalyst |
1 |
|
comos phase |
1 |
|
complex hydride |
1 |
|
composite |
1 |
|
composites |
1 |
|
computational simulation |
1 |
|
conjugate heat transfer |
1 |
|
continuous wire casting |
1 |
|
copper nanoparticle |
1 |
|
covalent bond |
1 |
|
covalent triazine framework-0 |
1 |
|
covalent triazine frameworks |
1 |
|
covalent triazine-based frameworks |
1 |
|
creep |
1 |
|
crude glycerol pretreatment |
1 |
|
crystal structure |
1 |
|
crystals |
1 |
|
cube texture |
1 |
|
cuco s nanocrystals 2 4 |
1 |
|
d-band center |
1 |
|
d. crystal structure |
1 |
|
d. ferroelectricity |
1 |
|
d. thermal expansion |
1 |
|
damping capacity |
1 |
|
debinding |
1 |
|
defect-free 2h-mos2 |
1 |
|
defects |
1 |
|
deformability |
1 |
|
deformation twinning |
1 |
|
density functional calculations |
1 |
|
dft calculations |
1 |
|
different treatments |
1 |
|
diffraction |
1 |
|
diffusion |
1 |
|
diffusion bonding |
1 |
|
dislocations |
1 |
|
dynamic recrystallisation |
1 |
|
dynamic recrystallization |
1 |
|
e. ab-initio calculations |
1 |
|
elastic modulus |
1 |
|
electrocatalyst |
1 |
|
electrochemical reactions |
1 |
|
electrochemical water splitting |
1 |
|
electrode materials |
1 |
|
electronic metal−substrate interactions |
1 |
|
electronic structure |
1 |
|
electronic structure of metals and alloys |
1 |
|
electropolishing |
1 |
|
energy storage |
1 |
|
energy storage materials |
1 |
|
entropy |
1 |
|
exoelectrogen |
1 |
|
fast pyrolysis |
1 |
|
fibre |
1 |
|
fibre chemistry |
1 |
|
fibre coating |
1 |
|
fibre composites |
1 |
|
fibre distribution |
1 |
|
field‐effect transistors |
1 |
|
filamentary macroporous structure |
1 |
|
film electrodes |
1 |
|
fine microstructure |
1 |
|
finite element analysis |
1 |
|
finite element modelling |
1 |
|
finite element simulation |
1 |
|
first principle |
1 |
|
first principles |
1 |
|
first-principle calculation |
1 |
|
first-principles calculation |
1 |
|
first-principles study |
1 |
|
flexible devices |
1 |
|
flexible electrodes |
1 |
|
flow induced mass transfer |
1 |
|
fluid dynamics |
1 |
|
fluorides |
1 |
|
fuel cell |
1 |
|
gas separation |
1 |
|
gas storage |
1 |
|
gas-solid reactions |
1 |
|
geometric effect |
1 |
|
germanium cluster |
1 |
|
glassy graphene |
1 |
|
glassy-graphene |
1 |
|
graded bandgaps |
1 |
|
grain boundaries |
1 |
|
grain boundary |
1 |
|
grain boundary sliding |
1 |
|
grain growth |
1 |
|
graphitic carbon nitride |
1 |
|
group iv elements |
1 |
|
heat transfer |
1 |
|
helical electrode |
1 |
|
heterojunction |
1 |
|
heterostructure coupling |
1 |
|
heterostructures |
1 |
|
hierarchical graphene framework |
1 |
|
hierarchical porous structure |
1 |
|
high temperature |
1 |
|
high-temperature oxidation |
1 |
|
homojunctions |
1 |
|
hrtem |
1 |
|
hydride |
1 |
|
hydrides |
1 |
|
hydrogen |
1 |
|
hydrogen bond |
1 |
|
hydrogen fuel |
1 |
|
hydrogen production |
1 |
|
hydrogen-aided processing |
1 |
|
hydrothermal reduction |
1 |
|
ii-vi semiconductors |
1 |
|
ilmenite |
1 |
|
in situ transmission electron microscopy |
1 |
|
in-situ transmission electron microscope |
1 |
|
initial concentration |
1 |
|
injection moulding |
1 |
|
inorganic compounds |
1 |
|
intercalation |
1 |
|
interface |
1 |
|
interface layer |
1 |
|
interface microstructure |
1 |
|
interfacial defects |
1 |
|
interfacial reaction |
1 |
|
interfacial reactions |
1 |
|
intergranular decohesion |
1 |
|
interlayer spacings |
1 |
|
ionic liquid electrolytes |
1 |
|
ir radiation |
1 |
|
iron-based matrix composite |
1 |
|
kinetic modelling |
1 |
|
langmuir isotherm models |
1 |
|
lattice oxygen mechanism |
1 |
|
levoglucosan |
1 |
|
li-ion batteries |
1 |
|
life cycle assessment |
1 |
|
lignin-carbohydrate complex |
1 |
|
lignocellulose valorization |
1 |
|
lignocellulosic biomass |
1 |
|
liquid sensing |
1 |
|
lithium hydride |
1 |
|
maghemite |
1 |
|
magnesium alloy |
1 |
|
magnesium alloys |
1 |
|
magnesium borohydride |
1 |
|
magnesium borohydride diammoniate |
1 |
|
magnetism |
1 |
|
matrix chemistry |
1 |
|
mechanical alloying (ma) |
1 |
|
membrane |
1 |
|
mesopores |
1 |
|
mesoporous photocatalytic hydrogen evolution reaction |
1 |
|
mesoscale simulation |
1 |
|
metal |
1 |
|
metal hydride |
1 |
|
metal matrix composites (mmc) |
1 |
|
metal oxides |
1 |
|
metal oxygen covalency |
1 |
|
metal-organic frameworks |
1 |
|
metallic materials |
1 |
|
metal‐matrix composite |
1 |
|
metal–organic framework |
1 |
|
metal−organic frameworks |
1 |
|
metastable β titanium alloy |
1 |
|
methane storage |
1 |
|
mg (al, zn) 32 49 |
1 |
|
mg-zn-al |
1 |
|
mg-zn-al alloys |
1 |
|
mgzn |
1 |
|
micro-arc oxidation |
1 |
|
micro-porous carbon |
1 |
|
micro-supercapacitors |
1 |
|
microbial fuel cell |
1 |
|
microbial fuel cell (mfc) |
1 |
|
microstructural evolution |
1 |
|
microstructural modelling |
1 |
|
microstructure |
1 |
|
migration |
1 |
|
miniaturized electronics |
1 |
|
mobility |
1 |
|
modelling |
1 |
|
modulus |
1 |
|
molecular beam epitaxy |
1 |
|
molecular dynamics |
1 |
|
molecular dynamics simulations |
1 |
|
molecular structure |
1 |
|
multifunctional device |
1 |
|
multiscale quasicontinuum method |
1 |
|
multiscale simulations |
1 |
|
n-doped carbon |
1 |
|
n-doped rgo |
1 |
|
nanoindentation |
1 |
|
nanoparticle |
1 |
|
nanorods |
1 |
|
nanotube |
1 |
|
natural organic matters |
1 |
|
neural network modeling |
1 |
|
nitridation |
1 |
|
nitride |
1 |
|
nitrides |
1 |
|
nitrogen doping |
1 |
|
numerical modelling |
1 |
|
o adsorption 2 |
1 |
|
oer |
1 |
|
onset plasticity |
1 |
|
orr |
1 |
|
overall water splitting |
1 |
|
oxide scales |
1 |
|
oxygen doping |
1 |
|
patterned line |
1 |
|
pbe-ts+scs |
1 |
|
perovskites |
1 |
|
phase diagram |
1 |
|
phase transformation |
1 |
|
phonon |
1 |
|
photo-oxidation |
1 |
|
photocatalytic oxygen production |
1 |
|
photodetection |
1 |
|
photodetector arrays |
1 |
|
photodetectors |
1 |
|
photothermal therapy |
1 |
|
phototransistors |
1 |
|
plasticity |
1 |
|
platelet boundary |
1 |
|
polyisobutylene |
1 |
|
polyisobutylene (pib) |
1 |
|
polymer |
1 |
|
polymer debinding |
1 |
|
polymer decomposition |
1 |
|
polymerization |
1 |
|
polymers |
1 |
|
porosity |
1 |
|
porous oxidation layer |
1 |
|
porous ti-24nb-4zr-8sn |
1 |
|
powder compact |
1 |
|
powder diffraction |
1 |
|
powder processing |
1 |
|
process simulation |
1 |
|
proton conduction |
1 |
|
protonation |
1 |
|
pt cocatalyst |
1 |
|
pt dopants |
1 |
|
quantum dots |
1 |
|
rare earth |
1 |
|
rare earth element |
1 |
|
reaction mechanism |
1 |
|
reaction synthesis |
1 |
|
reactive molecular dynamics (rmd) |
1 |
|
recrystallization |
1 |
|
recrystallization & recovery |
1 |
|
reduction in area |
1 |
|
reversibility |
1 |
|
rietveld analysis |
1 |
|
rolling forming |
1 |
|
ruthenium oxide |
1 |
|
salt templating |
1 |
|
scaling relationship |
1 |
|
self-powered |
1 |
|
self‐passivation |
1 |
|
self‐powered devices |
1 |
|
sic fiber |
1 |
|
sic fibre |
1 |
|
silica colloid |
1 |
|
silicon carbide fibres |
1 |
|
simulation |
1 |
|
simulations |
1 |
|
single vacancy defect |
1 |
|
single-atom catalysts |
1 |
|
sintering |
1 |
|
site preference |
1 |
|
slurry powder metallurgy |
1 |
|
solid solution nitride |
1 |
|
solid state reaction |
1 |
|
solid-state composites |
1 |
|
solidification |
1 |
|
solidification microstructure |
1 |
|
spark plasma sintering (sps) |
1 |
|
spin-forbidden reaction |
1 |
|
stability |
1 |
|
stacking fault energy |
1 |
|
strain |
1 |
|
strain engineering |
1 |
|
strength |
1 |
|
stress - strain curve |
1 |
|
structural cross-link |
1 |
|
superacidity |
1 |
|
supercapacitor |
1 |
|
supercapacitors |
1 |
|
surface coating |
1 |
|
swnt |
1 |
|
synergistic effect |
1 |
|
tensile strength |
1 |
|
ternary bimetal chalcogenides |
1 |
|
theoretical strength |
1 |
|
theory & modeling |
1 |
|
theory & modelling |
1 |
|
thermal decomposition |
1 |
|
thermal expansion |
1 |
|
thermal exposure |
1 |
|
thermal properties |
1 |
|
thermal reduction |
1 |
|
thermodynamic |
1 |
|
thermodynamic properties |
1 |
|
thermomechanical processing |
1 |
|
ti alloys |
1 |
|
ti alnb 2 |
1 |
|
ti composite |
1 |
|
ti-24nd-4zr-7.9sn alloy |
1 |
|
ti-6al-4v |
1 |
|
ti-6al-4v alloy |
1 |
|
ti/sicf |
1 |
|
tial alloys |
1 |
|
tial compound |
1 |
|
tib needle |
1 |
|
tih 2 |
1 |
|
titanium |
1 |
|
titanium alumindes |
1 |
|
titanium aluminides |
1 |
|
titanium aluminides, based on tial |
1 |
|
titanium carbonitride |
1 |
|
titanium dioxide |
1 |
|
titanium-matrix composites |
1 |
|
titanium-niobium-tantalum-zirconium alloy |
1 |
|
transition metal compounds |
1 |
|
transition metal dichalcogenide |
1 |
|
transition metal dichalcogenides |
1 |
|
transition metal doped silicon cluster |
1 |
|
tungsten nitride |
1 |
|
two-phase alloys |
1 |
|
ultrasmall magnetic resonance imaging |
1 |
|
van der waals interactions |
1 |
|
visible-light-driven photocatalysis |
1 |
|
volatile organic compounds |
1 |
|
wastewater treatment |
1 |
|
wear |
1 |
|
wet-spinning |
1 |
|
wide operation window |
1 |
|
wilson transition |
1 |
|
wire co-winding |
1 |
|
wox |
1 |
|
wse2 |
1 |
|
x‐ray mapping |
1 |
|
yarn |
1 |
|
yield phenomena |
1 |
|
young's modulus |
1 |
|
yttrium-molybdate |
1 |
|
zinc |
1 |
|
zinc-air battery |
1 |
|
zn-air battery |
1 |
|
α/β interface |
1 |
|
γ-tial based alloy |
1 |
|
化合物 |
1 |
|
合金元素 |
1 |
|
合金元素 (alloying elements) |
1 |
|
多电子转移 |
1 |
|
活性位点 |
1 |
|
电化学催化 |
1 |
|
相图 |
1 |
|
组织 |
1 |
|
组织与性能 (microstructure and properties) |
1 |
|
镁合金 |
1 |
|
镁合金 (magnesium alloys) |
1 |
