|
physics engineering |
5 |
|
binder |
3 |
|
energy storage |
3 |
|
flexible |
3 |
|
halogen cathode |
3 |
|
low-dimensional perovskites |
3 |
|
metal–halogen batteries |
3 |
|
vanadium oxide |
3 |
|
zinc ion batteries |
3 |
|
active iodine ligands |
2 |
|
active solid interhalogen chemistry |
2 |
|
aqueous redox-flow batteries (arfbs) |
2 |
|
aqueous zinc-iodine batteries |
2 |
|
aqueous zn battery |
2 |
|
bis-ammonium salts |
2 |
|
boron |
2 |
|
boron nitride nanotube |
2 |
|
bottlebrush polymer |
2 |
|
br0 fixing |
2 |
|
cathode materials |
2 |
|
conversion-type batteries |
2 |
|
conversion-type cathodes |
2 |
|
cycling stability |
2 |
|
dion–jacobson tin-iodide perovskites |
2 |
|
electrochemical energy storage |
2 |
|
electrochemical nitrogen reduction reaction |
2 |
|
energy density |
2 |
|
energy engineering |
2 |
|
eutectic effect |
2 |
|
flexible batteries |
2 |
|
fluorinated crosslinker |
2 |
|
free-standing electrode |
2 |
|
functionalization |
2 |
|
high cyclic stability |
2 |
|
high energy density |
2 |
|
high-concentration cl− |
2 |
|
high-energy zinc batteries |
2 |
|
high-loading mass cathode |
2 |
|
hollow spheres |
2 |
|
hybrid solar cells |
2 |
|
hydrogels |
2 |
|
hydrogen bond |
2 |
|
hydrogen storage |
2 |
|
improved kinetics |
2 |
|
in situ polymerized |
2 |
|
interface stability |
2 |
|
iodine |
2 |
|
lean-water |
2 |
|
leverage relationship |
2 |
|
li-cl2 batteries |
2 |
|
lithium batteries |
2 |
|
lithium ion batteries |
2 |
|
lithium metal anode |
2 |
|
lithium metal battery |
2 |
|
lithium-ion batteries |
2 |
|
map 5: improvement |
2 |
|
molecular catalyst |
2 |
|
multi-electron reactions |
2 |
|
nanotubes |
2 |
|
nitrides |
2 |
|
organic bulk heterojunction |
2 |
|
perovskite |
2 |
|
perovskite cathode |
2 |
|
polyether electrolyte |
2 |
|
polymer electrolyte |
2 |
|
proton transfer |
2 |
|
safe halide cathodes |
2 |
|
shuttle effect |
2 |
|
solid polymer electrolytes |
2 |
|
solid-state batteries |
2 |
|
solid-state battery |
2 |
|
strong chemisorption |
2 |
|
supercapacitor |
2 |
|
suppressed shuttle effect |
2 |
|
surface modification |
2 |
|
synthesis |
2 |
|
tin-iodide perovskites |
2 |
|
wearable sensor |
2 |
|
zinc dendrites |
2 |
|
zinc-air battery |
2 |
|
zinc-ion batteries |
2 |
|
zn powder anode |
2 |
|
zwitterionic polymer |
2 |
|
|
1 |
|
"white graphene" |
1 |
|
2 d porous materials |
1 |
|
2-methylimidazole |
1 |
|
2600 h lifespan |
1 |
|
2d materials |
1 |
|
3d architecture |
1 |
|
3d graphene fibers |
1 |
|
3d printing |
1 |
|
3d skeletons |
1 |
|
3d spacer fabric |
1 |
|
3d spacer fabrics |
1 |
|
a. bn nanotube |
1 |
|
a. boron nitride |
1 |
|
a. nanostructures |
1 |
|
a. porous foam |
1 |
|
a. semiconductor |
1 |
|
a. semiconductors |
1 |
|
ab initio calculation |
1 |
|
accumulation effect |
1 |
|
acetonitrile |
1 |
|
acetylenic linkage weakening |
1 |
|
acid electrolyte |
1 |
|
acid-alkaline electrolyte |
1 |
|
acid/alkali-free etchant |
1 |
|
acidic battery |
1 |
|
acidic nh3 synthesis |
1 |
|
activation |
1 |
|
active site |
1 |
|
active site exposure |
1 |
|
active sites |
1 |
|
active species |
1 |
|
adhesive hydrogels |
1 |
|
adsorption |
1 |
|
adsorption and desorption abilities |
1 |
|
aerogel |
1 |
|
aggregation-induced emission enhancement |
1 |
|
ain |
1 |
|
air chargeable |
1 |
|
air-rechargeable |
1 |
|
al-ion supercapacitors |
1 |
|
alkaline electrolytes |
1 |
|
alkaline zinc batteries |
1 |
|
alkaline zn batteries |
1 |
|
alkaline-tolerance |
1 |
|
alkaline-tolerant |
1 |
|
alkaline-tolerant stretchability |
1 |
|
alkylation |
1 |
|
all-in-one |
1 |
|
all-polymer approach |
1 |
|
all-polymer design |
1 |
|
all-solid-state |
1 |
|
all-solid-state batteries |
1 |
|
alloy catalyst |
1 |
|
alloy catalysts |
1 |
|
alloy materials |
1 |
|
aluminum |
1 |
|
aluminum nitride |
1 |
|
ammonia electrosynthesis |
1 |
|
ammonia synthesis |
1 |
|
ammonium ion batteries |
1 |
|
ammonium-ion batteries |
1 |
|
amorphous calcium carbonate |
1 |
|
amorphous sei for zn metal anode |
1 |
|
amphiphilic hydrogel electrolyte |
1 |
|
amphiphilic polymer chains |
1 |
|
analytical electron microscopy |
1 |
|
anhydride |
1 |
|
anion redox |
1 |
|
anion-cation competition chemistry |
1 |
|
anion-trap |
1 |
|
anions |
1 |
|
anisotropic pathways |
1 |
|
anode |
1 |
|
anode corrosion |
1 |
|
anode materials |
1 |
|
anode modifications |
1 |
|
anti-corrosion |
1 |
|
anti-corrosion property |
1 |
|
anti-dehydration |
1 |
|
anti-drying |
1 |
|
anti-freezing |
1 |
|
anti-oxidation |
1 |
|
anti-self-discharge |
1 |
|
antifreezing |
1 |
|
antifreezing electrocatalyst |
1 |
|
antifreezing electrolyte |
1 |
|
antioxidation |
1 |
|
applications |
1 |
|
aqueous acidic batteries |
1 |
|
aqueous al-ion batteries |
1 |
|
aqueous alkaline batteries |
1 |
|
aqueous aluminum ion batteries |
1 |
|
aqueous aluminum ion capacitors |
1 |
|
aqueous batteries |
1 |
|
aqueous battery |
1 |
|
aqueous capacitors |
1 |
|
aqueous electrolyte |
1 |
|
aqueous electrolyte batteries |
1 |
|
aqueous energy storage |
1 |
|
aqueous k-ion battery |
1 |
|
aqueous k-ion capacitor |
1 |
|
aqueous li batteries |
1 |
|
aqueous lithium-ion batteries |
1 |
|
aqueous lithium-ion battery |
1 |
|
aqueous magnesium-ion batteries |
1 |
|
aqueous metal ion batteries |
1 |
|
aqueous metal-ion batteries |
1 |
|
aqueous na-ion battery |
1 |
|
aqueous rechargeable battery |
1 |
|
aqueous supercapacitor |
1 |
|
aqueous zinc batteries |
1 |
|
aqueous zinc-based batteries |
1 |
|
aqueous zinc-ion batteries |
1 |
|
aqueous zinc-organic batteries |
1 |
|
aqueous zn |
1 |
|
aqueous zn batteries |
1 |
|
aqueous zn-ion batteries |
1 |
|
aqueous zn–i2 batteries |
1 |
|
aqueous/organic hybrid electrolyte |
1 |
|
aromatic molecules |
1 |
|
arsenic adsorption |
1 |
|
artificial interfaces |
1 |
|
artificial leather |
1 |
|
artificial n2fixation |
1 |
|
artificial protective layer |
1 |
|
assembly |
1 |
|
asymmetric capacitors |
1 |
|
asymmetric oxygen vacancy |
1 |
|
asymmetric supercapacitors |
1 |
|
atmospheric pressure chemical vapor deposition |
1 |
|
atomic fabrication |
1 |
|
atomic force microcopy |
1 |
|
atomic force microscopy |
1 |
|
atomic force microscopy (afm) |
1 |
|
atomically dispersed fe catalyst |
1 |
|
au nanoparticle |
1 |
|
aucu pentacle nanoparticle |
1 |
|
azo organic polymers |
1 |
|
b. chemical synthesis |
1 |
|
ball-milling |
1 |
|
basic zinc salts |
1 |
|
batteries |
1 |
|
batteries - aqueous |
1 |
|
battery materials |
1 |
|
battery-sensor system |
1 |
|
bcn nanotubes |
1 |
|
bending test |
1 |
|
bifuncational catalyst |
1 |
|
bifunctional catalysts |
1 |
|
bifunctional electrocatalyst |
1 |
|
bifunctional oxygen catalyst |
1 |
|
bifunctional oxygen catalysts |
1 |
|
bimetallic nickel cobalt phosphide |
1 |
|
bimetallic sulfides |
1 |
|
binder design |
1 |
|
binders |
1 |
|
binding mechanism |
1 |
|
biocompatibility |
1 |
|
bioi nanopaper |
1 |
|
biomimetic electrolyte |
1 |
|
biomimetic organohydrogel |
1 |
|
biomolecule |
1 |
|
biopolymers |
1 |
|
bismuth fluoride |
1 |
|
bismuth sulfide |
1 |
|
bismuth-antimony alloy |
1 |
|
bismuth-iodide perovskite cathodes |
1 |
|
bn nanosheet |
1 |
|
bn nanospheres |
1 |
|
bn nanotubes |
1 |
|
boron carbonitride |
1 |
|
boron nanotubes |
1 |
|
boron nanowires |
1 |
|
boron nitride |
1 |
|
boron nitride (bn) |
1 |
|
boron nitride (bn) nanotube |
1 |
|
boron nitride coating |
1 |
|
boron nitride nanoplatelets |
1 |
|
boron nitride nanoribbons |
1 |
|
boron nitride nanosheet |
1 |
|
boron nitride nanosheets |
1 |
|
boron nitride nanosphere |
1 |
|
boron nitride nanospheres |
1 |
|
boron nitride nanotubes |
1 |
|
boron nitride powder |
1 |
|
br2 batteries |
1 |
|
bromine phase |
1 |
|
bromine redox reaction |
1 |
|
bulk solvation |
1 |
|
by-product evolution |
1 |
|
c-coordinated fe |
1 |
|
c. three-dimensional structure |
1 |
|
calcium ion batteries |
1 |
|
calcium-ion batteries |
1 |
|
calcium-ion battery |
1 |
|
calendar aging |
1 |
|
camouflage |
1 |
|
cancer therapy |
1 |
|
capacitive strain sensors |
1 |
|
capacity enhancement |
1 |
|
carbon host materials |
1 |
|
carbon materials |
1 |
|
carbon nanotube |
1 |
|
carbon nanotubes |
1 |
|
carbon nanotubes(cnts) |
1 |
|
carbonyl groups |
1 |
|
carboxylated polyurethane |
1 |
|
carboxylic organic ligands |
1 |
|
carrier dynamics |
1 |
|
cascade conversion reaction |
1 |
|
catalysis |
1 |
|
catalyst |
1 |
|
catalyst-electrolyte interface |
1 |
|
cathode |
1 |
|
cathode dissolution |
1 |
|
cathode electrode |
1 |
|
cathode electrolyte interphase |
1 |
|
cation engineering |
1 |
|
cationic cellulose |
1 |
|
cationic modification |
1 |
|
ceramics |
1 |
|
characterization |
1 |
|
charge collision |
1 |
|
charge transfer |
1 |
|
charge voltage |
1 |
|
charge-deficient catalyst |
1 |
|
chemical affinity |
1 |
|
chemical blowing |
1 |
|
chemical bonding |
1 |
|
chemical modification |
1 |
|
chemical vapor deposition |
1 |
|
chemistry |
1 |
|
chitosan |
1 |
|
chloralkali industry |
1 |
|
chloride redox |
1 |
|
chlorine evolution reaction |
1 |
|
cnt/mno2 |
1 |
|
co(oh)2 |
1 |
|
co-doped biobr |
1 |
|
co-production |
1 |
|
co2 conversion |
1 |
|
coating |
1 |
|
cobalt hexacyanoferrate |
1 |
|
cobalt pillared |
1 |
|
cobalt polyphthalocyanine |
1 |
|
cocktail mediation effect |
1 |
|
compatibilizers |
1 |
|
competing oxygen evolution reaction |
1 |
|
composite |
1 |
|
composites |
1 |
|
compressibility |
1 |
|
compressible |
1 |
|
compressible devices |
1 |
|
compressible performance |
1 |
|
computational chemistry |
1 |
|
concentration fields |
1 |
|
conducting materials |
1 |
|
conductive cloth |
1 |
|
conductive yarn |
1 |
|
conductive yarns |
1 |
|
confined iodine |
1 |
|
confinement effect |
1 |
|
conjugated |
1 |
|
controlled release |
1 |
|
conversion chemistry |
1 |
|
conversion mechanism |
1 |
|
conversion mechanisms |
1 |
|
conversion reaction |
1 |
|
conversion-type cathode |
1 |
|
conversion-type mechanism |
1 |
|
conversion-type mechanisms |
1 |
|
coordinating solvents |
1 |
|
coordination engineering |
1 |
|
coordination regulation |
1 |
|
copper |
1 |
|
copper nanoclusters |
1 |
|
copper-based electrocatalyst |
1 |
|
core-spun yarn |
1 |
|
corrosion inhibition |
1 |
|
coulombic efficiency |
1 |
|
covalent functionalization |
1 |
|
covalent organic framework |
1 |
|
covalent organic frameworks |
1 |
|
cpg oligodeoxynucleotide |
1 |
|
cpg oligodeoxynucleotides |
1 |
|
crease-free |
1 |
|
cross-linking |
1 |
|
crown ether |
1 |
|
cryo-tem analysis |
1 |
|
crystal orientation engineering |
1 |
|
crystalline silicon solar cells |
1 |
|
crystalline water |
1 |
|
crystallographic reorientation |
1 |
|
cu-anode |
1 |
|
cu3pd nanoalloys |
1 |
|
cuhcf electrode |
1 |
|
current collector |
1 |
|
current density |
1 |
|
cuzn5 alloy |
1 |
|
cycle lifespan |
1 |
|
cycle performance |
1 |
|
cycling performance |
1 |
|
cyclopropenium |
1 |
|
cytokine |
1 |
|
cytokines |
1 |
|
d band theory |
1 |
|
d. electronic transport |
1 |
|
d. gas adsorption |
1 |
|
d. heat capacity |
1 |
|
d. synthesis |
1 |
|
deep eutectic solution |
1 |
|
deep eutectic solvents |
1 |
|
defect |
1 |
|
defect engineering |
1 |
|
defect reaction functionalization |
1 |
|
defective manganese hexacyanoferrate |
1 |
|
deformable batteries |
1 |
|
deformation structure |
1 |
|
degradable |
1 |
|
dendrite |
1 |
|
dendrite growth |
1 |
|
dendrite inhibition |
1 |
|
dendrite problem |
1 |
|
dendrite-free batteries |
1 |
|
dendrite-free property |
1 |
|
dendrite-free zn anodes |
1 |
|
dendrites |
1 |
|
dendrites suppression |
1 |
|
density functional theory |
1 |
|
deposition–dissolution mechanism |
1 |
|
descriptor |
1 |
|
desinged movements |
1 |
|
desolvation |
1 |
|
desolvation shield |
1 |
|
dft calculation |
1 |
|
dft calculations |
1 |
|
dft simulation |
1 |
|
diatomic pt-ce |
1 |
|
dielectric constant |
1 |
|
dielectric properties |
1 |
|
diffusion kinetics |
1 |
|
dimethyl carbonate |
1 |
|
direct ethanol fuel cell |
1 |
|
direct ink writing |
1 |
|
discharge plateau |
1 |
|
dispersion. |
1 |
|
dispersions |
1 |
|
dispersity |
1 |
|
distribution of relaxation times |
1 |
|
dna |
1 |
|
dna assay |
1 |
|
domain |
1 |
|
dopamine detection |
1 |
|
dopant |
1 |
|
double crosslinking networks |
1 |
|
double-layer capacitance |
1 |
|
double-network hydrogels |
1 |
|
doxorubicin |
1 |
|
drop-and-play function |
1 |
|
drug delivery |
1 |
|
dual electrode-electrolyte interfaces |
1 |
|
dual electrolyte–electrode interfaces |
1 |
|
dual single-atom catalysts |
1 |
|
dual-ion batteries |
1 |
|
dual-mode |
1 |
|
dual-network |
1 |
|
ductility |
1 |
|
durability |
1 |
|
durable and fast k-ion storage |
1 |
|
dynamic interface contact |
1 |
|
efficient cation migration |
1 |
|
elastic supercapacitors |
1 |
|
electric double layer |
1 |
|
electrical conductivity |
1 |
|
electrical properties |
1 |
|
electrically insulating |
1 |
|
electrocatalysis |
1 |
|
electrocatalysts |
1 |
|
electrocatalytic h2o2 production |
1 |
|
electrochemical capacitor |
1 |
|
electrochemical capacitors |
1 |
|
electrochemical co2 fixation |
1 |
|
electrochemical engineering |
1 |
|
electrochemical etching |
1 |
|
electrochemical her |
1 |
|
electrochemical n 2 reduction |
1 |
|
electrochemical n2oxidation |
1 |
|
electrochemical nitrate reduction |
1 |
|
electrochemical nitrogen reduction |
1 |
|
electrochemical no3− reduction |
1 |
|
electrochemical performance |
1 |
|
electrochemical properties |
1 |
|
electrochemical property |
1 |
|
electrochemical reaction |
1 |
|
electrochemical stability window |
1 |
|
electrochemical treatments |
1 |
|
electrochemistry |
1 |
|
electrochromic |
1 |
|
electrochromism |
1 |
|
electrode |
1 |
|
electrode engineering |
1 |
|
electrode materials |
1 |
|
electrode morphology |
1 |
|
electrode reaction |
1 |
|
electrodeposition |
1 |
|
electrohealing |
1 |
|
electroless plating |
1 |
|
electrolyte additives |
1 |
|
electrolyte design |
1 |
|
electrolyte engineering |
1 |
|
electrolytes |
1 |
|
electrolytes regulation |
1 |
|
electromagnetic shielding |
1 |
|
electron cloud |
1 |
|
electron diffraction |
1 |
|
electron transfer |
1 |
|
electron transport |
1 |
|
electron-donating capability |
1 |
|
electronic engineering |
1 |
|
electronic structure |
1 |
|
electronics |
1 |
|
electropolymerization |
1 |
|
energy conversion |
1 |
|
energy dissipation |
1 |
|
energy efficiency |
1 |
|
energy storage and conversion |
1 |
|
energy storage device |
1 |
|
energy storage devices |
1 |
|
energy storage material |
1 |
|
energy storage mechanism |
1 |
|
energy storage mechanisms |
1 |
|
energy storage textiles |
1 |
|
energy-dissipative |
1 |
|
enhanced synergistic effect |
1 |
|
enhancing electrochemistry |
1 |
|
enlarged ion transportation tunnels |
1 |
|
entanglement |
1 |
|
environmental adaption |
1 |
|
environmental adaptive |
1 |
|
environmental stability |
1 |
|
epoxy composites |
1 |
|
ether solvent |
1 |
|
eutectic electrolytes |
1 |
|
exfoliation |
1 |
|
f-doping |
1 |
|
fabrication |
1 |
|
faceting |
1 |
|
facets |
1 |
|
facile synthesis method |
1 |
|
faradaic redox reactions |
1 |
|
fast diffusion |
1 |
|
fast redox kinetics |
1 |
|
fe 3d electron delocalization |
1 |
|
fe, n doped |
1 |
|
fe2o3 |
1 |
|
fe3o4 |
1 |
|
feld emission array (fea) |
1 |
|
feooh |
1 |
|
ferric ions |
1 |
|
few-atomic-layered nanosheets |
1 |
|
fiber-shape zabs |
1 |
|
fiber-shaped |
1 |
|
fiber/yarn-based flexible supercapacitors |
1 |
|
field emission |
1 |
|
field(or bias) assistant hot flament chemical vacoor deposition (fahf-cvd) |
1 |
|
field-effect transistors |
1 |
|
flame-retardancy |
1 |
|
flavin mononucleotide |
1 |
|
flexibility |
1 |
|
flexible ag//zn battery |
1 |
|
flexible and multifunctional energy storage |
1 |
|
flexible and wearable supercapacitors |
1 |
|
flexible conductor |
1 |
|
flexible devices |
1 |
|
flexible electrodes |
1 |
|
flexible electrolytes |
1 |
|
flexible electronics |
1 |
|
flexible energy storage |
1 |
|
flexible energy storage devices |
1 |
|
flexible energy-storage devices |
1 |
|
flexible hybrid zn batteries |
1 |
|
flexible lithium-ion batteries |
1 |
|
flexible materials |
1 |
|
flexible na-ion capacitor |
1 |
|
flexible ni//zn battery |
1 |
|
flexible quasi-solid-state battery |
1 |
|
flexible rechargeable zinc-ion batteries |
1 |
|
flexible supercapacitors |
1 |
|
flexible zinc ion battery |
1 |
|
flexible zn batteries |
1 |
|
flexible zn-air batteries |
1 |
|
flexible/wearable |
1 |
|
flexible/wearable batteries |
1 |
|
flexible/wearable devices |
1 |
|
flexible supercapacitors |
1 |
|
fluid |
1 |
|
fluorescence |
1 |
|
fluoride-ion batteries |
1 |
|
fluorinated electrolytes |
1 |
|
fluorine-lodged layered double hydroxide (ldh) |
1 |
|
fmca assay |
1 |
|
folic acid |
1 |
|
freestanding polymer film |
1 |
|
full battery |
1 |
|
full-temperature range |
1 |
|
furfural-no3− battery |
1 |
|
galvanic corrosion |
1 |
|
gas chromatography-tandem mass spectrometry |
1 |
|
geited cnts/fea flat panel character display tube (fct) |
1 |
|
gel polymer electrolyte |
1 |
|
gelation |
1 |
|
glass transition |
1 |
|
gold |
1 |
|
gold leaf gilding |
1 |
|
grain boundaries |
1 |
|
graphdiyne |
1 |
|
graphene |
1 |
|
graphite-like layered structure |
1 |
|
graphitic carbon nitride |
1 |
|
gravity-induced gradient cu nanoparticles |
1 |
|
h+/zn2+ intercalation chemistry |
1 |
|
h2 evolution |
1 |
|
halide cathode |
1 |
|
halide insertion chemistry |
1 |
|
halogen |
1 |
|
halogen batteries |
1 |
|
halogen battery |
1 |
|
halogen electrochemistry |
1 |
|
halogen regulation |
1 |
|
halogen-zn battery |
1 |
|
halogenated mxene |
1 |
|
haloid cathode |
1 |
|
hard carbon |
1 |
|
health monitoring |
1 |
|
hematite |
1 |
|
heteroatom |
1 |
|
heteroatoms doping |
1 |
|
heterogeneous catalysis |
1 |
|
heterogeneous seed |
1 |
|
heterointerfaces |
1 |
|
heterojunction |
1 |
|
hexagonal boron nitride |
1 |
|
hexagonal moo3 |
1 |
|
hierarchically bicontinuous |
1 |
|
high areal capacity |
1 |
|
high capacitance supercapacitors |
1 |
|
high capacity |
1 |
|
high coulombic efficiency |
1 |
|
high dielectric |
1 |
|
high energy and power battery |
1 |
|
high entropy |
1 |
|
high ionic conductivity |
1 |
|
high loading mass |
1 |
|
high pressure raman |
1 |
|
high rate |
1 |
|
high rates |
1 |
|
high reversibility |
1 |
|
high softness |
1 |
|
high valence |
1 |
|
high voltage |
1 |
|
high voltage window |
1 |
|
high volumetric capacities |
1 |
|
high- temperature battery |
1 |
|
high-areal-capacity |
1 |
|
high-concentration dispersion |
1 |
|
high-energy density |
1 |
|
high-entropy alloy |
1 |
|
high-index facets |
1 |
|
high-loading |
1 |
|
high-temperature batteries |
1 |
|
high-temperature shock |
1 |
|
high-voltage |
1 |
|
high-voltage aqueous electrolytes |
1 |
|
homogenized electrodes |
1 |
|
homologous heterostructures |
1 |
|
hosting potential compensation |
1 |
|
hybrid batteries |
1 |
|
hybrid composite |
1 |
|
hybrid coordination electrolyte |
1 |
|
hybrid electrolyte |
1 |
|
hybrid electrolytes |
1 |
|
hybrid materials |
1 |
|
hybrid zinc battery |
1 |
|
hybrid-ion batteries |
1 |
|
hydrogel |
1 |
|
hydrogel electrolyte |
1 |
|
hydrogel electrolytes |
1 |
|
hydrogels with targeted adhesion |
1 |
|
hydrogen bond chemistry |
1 |
|
hydrogen evolution |
1 |
|
hydrogen evolution reaction suppression |
1 |
|
hydrogen evolution suppression |
1 |
|
hydrogen radicals |
1 |
|
hydrogen substituted graphdiyne |
1 |
|
hydrogen-bonded ionic co-crystals |
1 |
|
hydrogen-substituted graphdiyne |
1 |
|
hydrolysis |
1 |
|
hydrophobic-unit-regulated hydrogel electrolytes |
1 |
|
hydrothermal |
1 |
|
imide |
1 |
|
immunostimulatory effect |
1 |
|
in situ microscopy |
1 |
|
in-layer channels |
1 |
|
inactive terminals |
1 |
|
industrial applications |
1 |
|
inner filling functionalization |
1 |
|
insertion mechanism |
1 |
|
insertion-conversion mechanism |
1 |
|
insulation |
1 |
|
integrated device |
1 |
|
integrated electronic textiles |
1 |
|
integrated wearable systems |
1 |
|
integration |
1 |
|
intercalation-type anode |
1 |
|
interface adhesion |
1 |
|
interfaces |
1 |
|
interfacial chemistry |
1 |
|
interfacial design |
1 |
|
interfacial spatial |
1 |
|
interhalogen bonds |
1 |
|
interhalogens |
1 |
|
interlayer spacing regulation |
1 |
|
interpenetrating encapsulation |
1 |
|
interplay |
1 |
|
intrinsic conductive fiber/yarn |
1 |
|
intrinsic nonconductive fiber/yarn |
1 |
|
intrinsic stretchability |
1 |
|
iodide electrolytes |
1 |
|
iodide-ion conversion |
1 |
|
iodine batteries |
1 |
|
iodine battery |
1 |
|
ion hopping |
1 |
|
ion mass transfer |
1 |
|
ion migration channels |
1 |
|
ion tunnels |
1 |
|
ion-separation |
1 |
|
ionic anchoring |
1 |
|
ionic conductivity |
1 |
|
ionic liquid |
1 |
|
ionic liquid films |
1 |
|
ionic liquids |
1 |
|
iron oxide |
1 |
|
iron-doped nickel phosphide |
1 |
|
isoleucine |
1 |
|
isotropic |
1 |
|
janus catholyte/cathode structure |
1 |
|
janus structures |
1 |
|
kinetics suppression |
1 |
|
knittability |
1 |
|
lab6 |
1 |
|
laser flash analysis |
1 |
|
lattice match |
1 |
|
lattice matching |
1 |
|
layer-by-layer assembly |
1 |
|
layered double hydroxides |
1 |
|
layered electrodes |
1 |
|
layered structure |
1 |
|
lead halide perovskites |
1 |
|
li-air battery |
1 |
|
li-oxygen batteries |
1 |
|
lidfp additive |
1 |
|
ligand substitution |
1 |
|
liquid transformation |
1 |
|
liquid-liquid phase separation |
1 |
|
lithiophilicity |
1 |
|
lithium metal anodes |
1 |
|
lithium metal batteries |
1 |
|
lithium polysulfides |
1 |
|
lithium-ion battery |
1 |
|
lithium-ion power batteries |
1 |
|
lithium-ions batteries |
1 |
|
lithium-sulfur batteries |
1 |
|
lithium–sulfur batteries |
1 |
|
li–i 2 batteries |
1 |
|
loading mass |
1 |
|
local environment |
1 |
|
localized surface plasmon resonance |
1 |
|
long calendar life |
1 |
|
long conjugate structure |
1 |
|
long cyclic life |
1 |
|
long lifespan |
1 |
|
long-term durability |
1 |
|
long-term stability |
1 |
|
longitudinal zinc growth |
1 |
|
low concentration of salts |
1 |
|
low dielectric constant |
1 |
|
low dielectric loss |
1 |
|
low temperature battery |
1 |
|
low-cost |
1 |
|
low-temperature batteries |
1 |
|
low-temperature energy storage |
1 |
|
low-valence zn atoms |
1 |
|
low-working temperature battery |
1 |
|
magnesium ion batteries |
1 |
|
magnesium ion battery |
1 |
|
magnesium-ion battery |
1 |
|
magnetic-assisted |
1 |
|
man-machine interaction |
1 |
|
manganese oxide |
1 |
|
map 6: development |
1 |
|
materials science |
1 |
|
mechanical performance |
1 |
|
mechanical properties |
1 |
|
mechanical strength |
1 |
|
mechanized production |
1 |
|
mediation of ion flux |
1 |
|
melt spinning |
1 |
|
melt-processable |
1 |
|
mesoporous silica |
1 |
|
metal anodes |
1 |
|
metal cobalt |
1 |
|
metal heterocyclic |
1 |
|
metal ion battery |
1 |
|
metal organic framework |
1 |
|
metal selenide derivatives |
1 |
|
metal sulfide anode |
1 |
|
metal-bromine battery |
1 |
|
metal-conductive cloth |
1 |
|
metal-free electrocatalysts |
1 |
|
metal-iodine battery |
1 |
|
metal-ion batteries |
1 |
|
metal-organic framework |
1 |
|
metal-support interactions |
1 |
|
metal-te batteries |
1 |
|
metal/covalent organic frameworks |
1 |
|
metallic materials |
1 |
|
metal–organic framework |
1 |
|
metal–organic frameworks |
1 |
|
methylammonium |
1 |
|
mg hybrid ion battery |
1 |
|
micro-redox capacitors |
1 |
|
micro-supercapacitors |
1 |
|
microbattery |
1 |
|
microbelts |
1 |
|
micropatterning |
1 |
|
microporous materials |
1 |
|
microwave-assisted synthesis |
1 |
|
mild silver-znic battery |
1 |
|
mineral hydrogels |
1 |
|
mn dissolution |
1 |
|
mn3+/mn2+ redox couple |
1 |
|
mn3o4cathode |
1 |
|
mno2 |
1 |
|
mno2 batteries |
1 |
|
mno2 cathode |
1 |
|
mno2 nanosheets |
1 |
|
mno2-cu/zn/bi batteries |
1 |
|
mo cluster |
1 |
|
modulization |
1 |
|
molecular crowding effect |
1 |
|
molecular crystals |
1 |
|
molecular dynamics |
1 |
|
molecular ordering |
1 |
|
molten salts |
1 |
|
mos2 |
1 |
|
mos2/pani cathode |
1 |
|
mtt assay |
1 |
|
multi-electron conversion |
1 |
|
multi-electron transfer |
1 |
|
multicolor light emission |
1 |
|
multielectron transfer |
1 |
|
multifunctional devices |
1 |
|
multifunctional energy storage device |
1 |
|
multifunctional energy storage devices |
1 |
|
multifunctionality |
1 |
|
multiple-yolk eggs |
1 |
|
multiroled battery |
1 |
|
multivalence metal ions |
1 |
|
multivalent batteries |
1 |
|
multivalent ion |
1 |
|
multivalent ion batteries |
1 |
|
multivalent ion battery |
1 |
|
multivalent ions |
1 |
|
multiwal carbon nanometer tubes(mcnts) |
1 |
|
mxene |
1 |
|
mxene family |
1 |
|
mxene host |
1 |
|
mxene nanosheets |
1 |
|
mxenes |
1 |
|
mxenes biosensors |
1 |
|
n-/p-type conversion |
1 |
|
n-doped |
1 |
|
n2 fixation |
1 |
|
na-zn hybrid electrolytes |
1 |
|
nano composites |
1 |
|
nano-mxenes |
1 |
|
nanobiomedicine |
1 |
|
nanocomposites |
1 |
|
nanocrystals |
1 |
|
nanodiamond |
1 |
|
nanofiber |
1 |
|
nanofibers |
1 |
|
nanofibrillated cellulose |
1 |
|
nanofibrillated cellulose/polyacrylamide hydrogel |
1 |
|
nanohybrid |
1 |
|
nanomaterials |
1 |
|
nanomechanics |
1 |
|
nanoparticle |
1 |
|
nanoplatelets |
1 |
|
nanoporous |
1 |
|
nanoribbon |
1 |
|
nanosheet |
1 |
|
nanosheets |
1 |
|
nanostructure |
1 |
|
nanostructures |
1 |
|
nanotube |
1 |
|
nanotubes oxidization |
1 |
|
nanowire |
1 |
|
nanowires |
1 |
|
nasicon-zn batteries |
1 |
|
near-field |
1 |
|
near-neutral electrolytes |
1 |
|
nematic phases |
1 |
|
neural engineering |
1 |
|
neutral electrolyte |
1 |
|
new battery chemistry |
1 |
|
new energy materials |
1 |
|
nh 3 production selectivity |
1 |
|
nh3 synthesis |
1 |
|
ni battery |
1 |
|
ni(oh)2 |
1 |
|
nickel selenide |
1 |
|
nickel–metal hydride batteries |
1 |
|
nicose2@niooh/coooh heterostructures |
1 |
|
nico–ch |
1 |
|
nitrate production |
1 |
|
nitrate reduction |
1 |
|
nitrate reduction reaction |
1 |
|
nitrogen |
1 |
|
nitrogen fixation |
1 |
|
nitrogen-doped carbon |
1 |
|
no2 reduction |
1 |
|
no3− reduction |
1 |
|
non-flow zinc-bromine batteries |
1 |
|
noncovalent functionalization |
1 |
|
noncovalent interactions |
1 |
|
nucleation |
1 |
|
nucleation overpotential |
1 |
|
oh-rich hydrogel electrolytes |
1 |
|
ohmic contact |
1 |
|
oil absorption |
1 |
|
omnidirectional deformable |
1 |
|
orbital angular momentum |
1 |
|
organic and inorganic components in sei |
1 |
|
organic anode materials |
1 |
|
organic anodes |
1 |
|
organic cathode |
1 |
|
organic cathode materials |
1 |
|
organic cathodes |
1 |
|
organic cocrystals |
1 |
|
organic electrode |
1 |
|
organic electrodes |
1 |
|
organic molecules |
1 |
|
organic nitro compounds |
1 |
|
organic salts |
1 |
|
organic-inorganic interface |
1 |
|
organic–inorganic hybridization |
1 |
|
organogels |
1 |
|
orientation |
1 |
|
orr/oer |
1 |
|
overcharge-cycling protocol |
1 |
|
oxidation |
1 |
|
oxides |
1 |
|
oxygen electrocatalytic reaction |
1 |
|
oxygen evolution reaction |
1 |
|
oxygen evolution reactions |
1 |
|
oxygen impurities |
1 |
|
oxygen reduction |
1 |
|
oxygen reduction reaction |
1 |
|
oxygen reduction reactions |
1 |
|
p-orbital delocalization |
1 |
|
particle synthesis |
1 |
|
patterning |
1 |
|
pbas cathode batteries |
1 |
|
pd cluster catalyst |
1 |
|
pedot |
1 |
|
pedot:pss |
1 |
|
perovskite solar cells |
1 |
|
perspective |
1 |
|
ph-responsive charge-reversal |
1 |
|
phase and structure transition |
1 |
|
phase design |
1 |
|
phase field model |
1 |
|
phonon polariton |
1 |
|
phosphorene |
1 |
|
photocatalysts |
1 |
|
photocatalytic activity |
1 |
|
photochemistry |
1 |
|
photodetector |
1 |
|
photodetectors |
1 |
|
photoexcited electron |
1 |
|
photoluminescence |
1 |
|
photoluminescent |
1 |
|
physical properties |
1 |
|
physical/chemical interaction |
1 |
|
piezoelectric effect |
1 |
|
piezoresistive |
1 |
|
plasmon |
1 |
|
poly(3,4-ethylenedioxythiophene):poly(4-styrenesulfonate) |
1 |
|
polyacrylamide |
1 |
|
polyacrylamide hydrogel electrolyte |
1 |
|
polyaniline |
1 |
|
polycyclic aromatic hydrocarbons |
1 |
|
polyethylene oxide |
1 |
|
polyethyleneimine |
1 |
|
polymer |
1 |
|
polymer composite |
1 |
|
polymer composites |
1 |
|
polymer electrolytes |
1 |
|
polymer-based supercapacitors |
1 |
|
polymer-inorganic bilayer solid electrolyte interphase |
1 |
|
polymer-matrix composites (pmcs) |
1 |
|
polymeric composite |
1 |
|
polymeric composites |
1 |
|
polymeric single-ion conductors |
1 |
|
polymers |
1 |
|
polyporous conductive frameworks |
1 |
|
polypyrrole |
1 |
|
polypyrrole film |
1 |
|
polypyrrole supercapacitors |
1 |
|
polystyrene microspheres |
1 |
|
pomegranate-like shell |
1 |
|
pore width |
1 |
|
porous |
1 |
|
porous carbon |
1 |
|
porous elastomer |
1 |
|
porous fe2o3 |
1 |
|
porous graphene |
1 |
|
porous nickel films |
1 |
|
porous single-crystal nati2(po4)3 |
1 |
|
porous structure |
1 |
|
porous zif-8 layer |
1 |
|
positive-valence conversion of sulfur |
1 |
|
post li-ion batteries |
1 |
|
potassium splitting |
1 |
|
pouch cell |
1 |
|
power density |
1 |
|
practical applications |
1 |
|
practical-level zn batteries |
1 |
|
pre-intercalation |
1 |
|
precise repairs |
1 |
|
pressure |
1 |
|
properties |
1 |
|
protective coatings |
1 |
|
protective layer |
1 |
|
proton battery |
1 |
|
proton holder feature |
1 |
|
proton-accessibility |
1 |
|
proton-regulated kinetics |
1 |
|
prussian blue |
1 |
|
prussian blue analog |
1 |
|
prussian blue analogies |
1 |
|
prussian blue analogue |
1 |
|
quantification of flexibility |
1 |
|
quantifying hydrogen evolution |
1 |
|
quantum degrees of freedom |
1 |
|
quantum dots |
1 |
|
quantum functional materials |
1 |
|
quasi solid battery |
1 |
|
quaternary ammonium |
1 |
|
raman spectroscopy |
1 |
|
rate capabilities |
1 |
|
rate capability |
1 |
|
rate performance |
1 |
|
rate-determining step |
1 |
|
reaction mechanism |
1 |
|
rechargeable |
1 |
|
rechargeable batteries |
1 |
|
rechargeable zinc air battery |
1 |
|
rechargeable zinc ion batteries |
1 |
|
rechargeable zinc ion battery |
1 |
|
rechargeable zinc-air battery |
1 |
|
rechargeable zn-mno 2 battery |
1 |
|
recommendations |
1 |
|
reconstructed vanadium oxide |
1 |
|
red blood cell |
1 |
|
redistributor |
1 |
|
redox couples |
1 |
|
redox flow batteries |
1 |
|
redox reactions |
1 |
|
redox-electrolytes |
1 |
|
reduced graphene oxide |
1 |
|
reduction |
1 |
|
remote light-emitting device |
1 |
|
residual doping effect |
1 |
|
residual strain |
1 |
|
reversibility of zn anode |
1 |
|
reversible anodes |
1 |
|
reversible transition |
1 |
|
reversible zinc plating/stripping |
1 |
|
rgo-based aerogel |
1 |
|
room-temperature gas sensor |
1 |
|
s-snom |
1 |
|
safety |
1 |
|
salt polarization |
1 |
|
sampling |
1 |
|
sandwich |
1 |
|
screen printing |
1 |
|
sdg11: sustainable cities and communities |
1 |
|
sdg6: clean water and sanitation |
1 |
|
sdg7: affordable and clean energy |
1 |
|
sdg9: industry, innovation, and infrastructure |
1 |
|
se reduction |
1 |
|
selective etching |
1 |
|
selectivity |
1 |
|
selenium nanowires |
1 |
|
self-capture |
1 |
|
self-charging |
1 |
|
self-discharge |
1 |
|
self-healability |
1 |
|
self-healable |
1 |
|
self-healing |
1 |
|
self-healing capabilities |
1 |
|
self-powered |
1 |
|
self-powered sensor |
1 |
|
self-templating |
1 |
|
sensors |
1 |
|
separators |
1 |
|
sewable battery |
1 |
|
shape memory |
1 |
|
shear resistance |
1 |
|
shelf-life |
1 |
|
shuttle-free |
1 |
|
shuttling effect |
1 |
|
silicon/carbon anode |
1 |
|
single atom catalyst |
1 |
|
single-atom catalyst |
1 |
|
single-phase transition |
1 |
|
single-site active sites |
1 |
|
single-wall carbon nanotube |
1 |
|
smart functional materials |
1 |
|
smart skins |
1 |
|
smart windows |
1 |
|
sodium ion batteries |
1 |
|
sodium polyacrylate |
1 |
|
sodium-ion batteries |
1 |
|
sodium-ion battery |
1 |
|
sodium-selenium battery |
1 |
|
softness |
1 |
|
sol-gel electrolyte |
1 |
|
solid batteries |
1 |
|
solid electrolyte interface |
1 |
|
solid electrolyte interphase |
1 |
|
solid electrolyte interphase protection layer |
1 |
|
solid electrolyte interphases |
1 |
|
solid electrolytes |
1 |
|
solid polymer electrolyte |
1 |
|
solid zn 2+-ion conductors |
1 |
|
solid-electrolyte interphase |
1 |
|
solid-liquid conversion |
1 |
|
solid-phase microextraction |
1 |
|
solid-polymer electrolytes |
1 |
|
solid-state |
1 |
|
solid-state electrolytes |
1 |
|
solid–electrolyte interphase |
1 |
|
solubility |
1 |
|
solvation sheath |
1 |
|
solvation structure |
1 |
|
solvation structures |
1 |
|
solvent-free fabrication |
1 |
|
sp-carbon contents |
1 |
|
specific capacitances |
1 |
|
specific surface area |
1 |
|
sphere |
1 |
|
spider silks |
1 |
|
spin coupling |
1 |
|
spin-state transition |
1 |
|
stability performance |
1 |
|
stable cyclability |
1 |
|
static battery |
1 |
|
stirrer |
1 |
|
strain sensors |
1 |
|
strain-gauge sensor |
1 |
|
stretch-induced performance degradation |
1 |
|
stretchability |
1 |
|
stretchable |
1 |
|
stretchable electrodes |
1 |
|
stretchable separators |
1 |
|
stretchable strain sensor |
1 |
|
stretchable supercapacitors |
1 |
|
stripping/plating |
1 |
|
strong interaction |
1 |
|
structural design |
1 |
|
structure analysis |
1 |
|
substrate versatility |
1 |
|
substrates |
1 |
|
subzero temperature batteries |
1 |
|
sulfur cathode |
1 |
|
sulfur cathodes |
1 |
|
sulfur doping strategy |
1 |
|
super-stretchable |
1 |
|
super-tough |
1 |
|
super-tough strain sensors |
1 |
|
supercapacitors |
1 |
|
superhydrophobicity |
1 |
|
superior cyclic stability |
1 |
|
superior durability |
1 |
|
superior rate capability |
1 |
|
superplasticity |
1 |
|
supported catalysts |
1 |
|
suppressed hydrogen evolution |
1 |
|
suppressed surface passivation |
1 |
|
supramolecular hydrogels |
1 |
|
surface atom knockout |
1 |
|
surface catalytic reactivity |
1 |
|
surface coating |
1 |
|
surface energy |
1 |
|
surface morphology |
1 |
|
surface tensile strain |
1 |
|
surface work function |
1 |
|
synergistic catalytic effects |
1 |
|
synergistic effect |
1 |
|
tactile sensor |
1 |
|
targeted delivery |
1 |
|
te negative electrodes |
1 |
|
technical difficulties |
1 |
|
tellurium |
1 |
|
tellurium anodes |
1 |
|
temperature |
1 |
|
temperature adaptability |
1 |
|
temperature dependence |
1 |
|
temperature effect |
1 |
|
temperature-dependent performance |
1 |
|
temperature-insensitive |
1 |
|
temperaturemodulated differential scanning calorimetry (dsc) |
1 |
|
tempo-oxidized cellulose nanofibers |
1 |
|
tensile |
1 |
|
terminal |
1 |
|
tetrazole |
1 |
|
textile geometry |
1 |
|
textiles |
1 |
|
theoretical calculations |
1 |
|
thermal chemical vapor deposition |
1 |
|
thermal conductivity |
1 |
|
thermal interface materials |
1 |
|
thermal properties |
1 |
|
thermal stability |
1 |
|
thermo-reversible hydrogel |
1 |
|
thermoresponsive |
1 |
|
ti 2ct x mxene spheres |
1 |
|
ti3c2 mxene |
1 |
|
ti3c2tx mxene |
1 |
|
ti3c2txmxene |
1 |
|
tight assembly state |
1 |
|
tin anode |
1 |
|
titanium dioxide |
1 |
|
titanium nitride |
1 |
|
tolerance enhancement |
1 |
|
torsion |
1 |
|
tortuosity |
1 |
|
tough |
1 |
|
transferable |
1 |
|
transition metal ion dissolution |
1 |
|
transition-metal carbides |
1 |
|
transmission electron microscopy |
1 |
|
transmission electron microscopy (tem) |
1 |
|
transparent |
1 |
|
triboelectric nanogenerator |
1 |
|
triboelectric nanogenerators |
1 |
|
triboelectric self-power |
1 |
|
trifunctional electrocatalysts |
1 |
|
tunable sensing range |
1 |
|
tungsten oxide |
1 |
|
two dimensional materials |
1 |
|
two dimensional polymers |
1 |
|
two reactive metal-sites |
1 |
|
two-dimensional crystal |
1 |
|
two-dimensional nanomaterials |
1 |
|
two-electron oxygen reduction |
1 |
|
two-electron redox |
1 |
|
two-electron transfer |
1 |
|
two-electron transfer iodine electrode |
1 |
|
two-species redox reaction |
1 |
|
ultra-flat |
1 |
|
ultra-flat voltage platform |
1 |
|
ultra-stable cycling ability |
1 |
|
ultraflat discharge plateaus |
1 |
|
ultrahigh mass loading |
1 |
|
ultralong cyclability |
1 |
|
ultralong lifespan |
1 |
|
ultralong lifetime |
1 |
|
ultralow-temperature-tolerant zinc air batteries |
1 |
|
ultrasmall nanoparticles |
1 |
|
ultrasonication |
1 |
|
unidirectional deformable |
1 |
|
urethane elastic fiber core spun yarn |
1 |
|
uv-shielding |
1 |
|
v2ctx mxene |
1 |
|
v2o5 |
1 |
|
vacancies-rich |
1 |
|
valence mediation |
1 |
|
valuable carbonaceous fuels |
1 |
|
value-added chemicals |
1 |
|
value-added product |
1 |
|
vanadium oxides |
1 |
|
vanadium-based materials |
1 |
|
vapor-infiltration method |
1 |
|
vertical alignment |
1 |
|
vertical graphene sheets |
1 |
|
vertical growth |
1 |
|
virus-like structure |
1 |
|
visible light emission |
1 |
|
voltage difference |
1 |
|
voltage plateau |
1 |
|
voltage plateaus |
1 |
|
w tip |
1 |
|
water splitting |
1 |
|
water states |
1 |
|
water-in-salt electrolyte |
1 |
|
waterproof |
1 |
|
weakened coulombic interactions |
1 |
|
weakly solvating effect |
1 |
|
wearability |
1 |
|
wearable |
1 |
|
wearable batteries |
1 |
|
wearable device |
1 |
|
wearable devices |
1 |
|
wearable electronic device |
1 |
|
wearable electronics |
1 |
|
wearable integrated power units |
1 |
|
wearable supercapacitor |
1 |
|
wearable supercapacitors |
1 |
|
wearable zinc batteries |
1 |
|
wearable zinc–air batteries |
1 |
|
weavability |
1 |
|
well-ordered water molecules |
1 |
|
wetting |
1 |
|
white graphene |
1 |
|
white led |
1 |
|
wood carbons |
1 |
|
working voltage |
1 |
|
ws2 nanotubes |
1 |
|
x-ray absorption near-edge structures |
1 |
|
x-ray excited optical luminescence |
1 |
|
yarn |
1 |
|
yarn battery |
1 |
|
yarn supercapacitor |
1 |
|
yarn supercapacitors |
1 |
|
yolk-shell structure |
1 |
|
zif-90-i |
1 |
|
zinc |
1 |
|
zinc air batteries (zabs) |
1 |
|
zinc anode |
1 |
|
zinc anodes |
1 |
|
zinc based batteries |
1 |
|
zinc batteries |
1 |
|
zinc battery |
1 |
|
zinc dendrite |
1 |
|
zinc deposition |
1 |
|
zinc hybrid-ion batteries |
1 |
|
zinc ion battery |
1 |
|
zinc ion capacitor |
1 |
|
zinc ion capacitors |
1 |
|
zinc ion intercalation |
1 |
|
zinc ion transfer kinetics |
1 |
|
zinc metal batteries |
1 |
|
zinc metal battery |
1 |
|
zinc perchlorate hexahydrate |
1 |
|
zinc powder anodes |
1 |
|
zinc reversibility |
1 |
|
zinc substrate |
1 |
|
zinc-air batteries |
1 |
|
zinc-based batteries |
1 |
|
zinc-based energy storage batteries |
1 |
|
zinc-bromine batteries |
1 |
|
zinc-iodine batteries |
1 |
|
zinc-ion battery |
1 |
|
zinc/sulfur batteries |
1 |
|
zincophilic interfaces |
1 |
|
zinc–air batteries |
1 |
|
zn |
1 |
|
zn anode |
1 |
|
zn anode reversibility |
1 |
|
zn anodes |
1 |
|
zn batteries |
1 |
|
zn batteries module |
1 |
|
zn corrosion |
1 |
|
zn dendrites |
1 |
|
zn deposition |
1 |
|
zn deposition regulation |
1 |
|
zn electrode/electrolyte interface |
1 |
|
zn ion batteries |
1 |
|
zn ion flux regulation |
1 |
|
zn metal anodes |
1 |
|
zn metal batteries |
1 |
|
zn plating behavior |
1 |
|
zn powder |
1 |
|
zn-air batteries |
1 |
|
zn-air battery |
1 |
|
zn-based batteries |
1 |
|
zn-based flow batteries |
1 |
|
zn-co2 battery |
1 |
|
zn-i2 battery |
1 |
|
zn-ion batteries |
1 |
|
zn-ion battery |
1 |
|
zn-ion capacitor |
1 |
|
zn-ion capacitors |
1 |
|
zn-mno 2 batteries |
1 |
|
zn-n2 battery |
1 |
|
zn-nitrate batteries |
1 |
|
zn-no battery |
1 |
|
zn-organic batteries |
1 |
|
zn//mno2 batteries |
1 |
|
zn/k hybrid batteries |
1 |
|
zno |
1 |
|
znophilic additive |
1 |
|
zn–co2 batteries |
1 |
|
zn–mno2 aqueous battery |
1 |
|
zwitterionic oligomer |
1 |
|
zwitterionic sulfobetaine |
1 |
|
α-fe2o3 |
1 |
|
δ-mno2 |
1 |
|
π- π interaction |
1 |
|
π-conjugated structure |
1 |
