|
photoluminescence |
8 |
|
physics engineering |
8 |
|
oled |
6 |
|
tris-(8-hydroxyquinoline) aluminium |
6 |
|
b1. nanomaterials |
5 |
|
b1. zinc compounds |
5 |
|
physics |
5 |
|
boundary integral equation (bie) |
4 |
|
electric power supplies |
4 |
|
finite element method (fem) |
4 |
|
generalized impedance boundary condition (gibc) |
4 |
|
nanostructures |
4 |
|
organic solar cell |
4 |
|
perovskites |
4 |
|
plasmonic nanostructures |
4 |
|
solar energy |
4 |
|
ultraviolet radiation |
4 |
|
zinc oxide |
4 |
|
2d grating |
3 |
|
absorption enhancement |
3 |
|
active layer |
3 |
|
active material |
3 |
|
active polymers |
3 |
|
angular response |
3 |
|
cavity devices |
3 |
|
chiral structure |
3 |
|
circular polarizer |
3 |
|
computer-aided design |
3 |
|
decay length |
3 |
|
design guidelines |
3 |
|
design principles |
3 |
|
dipole resonances |
3 |
|
dispersion relations |
3 |
|
driftdiffusion equations |
3 |
|
dye-sensitized solar cells (dssc) |
3 |
|
electric dyadic green's function |
3 |
|
electrical studies |
3 |
|
excited atoms |
3 |
|
exciton generation |
3 |
|
external quantum efficiency |
3 |
|
fano resonances |
3 |
|
finite difference |
3 |
|
finite size effect |
3 |
|
finite-difference frequency-domain method |
3 |
|
geometric configurations |
3 |
|
high efficiency |
3 |
|
lambert's cosine law |
3 |
|
light-emitting diodes |
3 |
|
membranes, artificial |
3 |
|
metallic loss |
3 |
|
morphology |
3 |
|
nanoantennas |
3 |
|
nanostrips |
3 |
|
near-field multiple scattering |
3 |
|
near-field scattering |
3 |
|
optical properties |
3 |
|
optical wavelength |
3 |
|
perovskite solar cell |
3 |
|
phosphorescence |
3 |
|
photon detection |
3 |
|
plasmonic |
3 |
|
polarization control |
3 |
|
polymer solar cells |
3 |
|
polymers - chemistry |
3 |
|
solar cells |
3 |
|
surface plasmon resonance - instrumentation |
3 |
|
wavelength selectivity |
3 |
|
workfunction |
3 |
|
working principles |
3 |
|
1,10-phenanthroline |
2 |
|
2d perovskite |
2 |
|
angular dependence |
2 |
|
au nanoparticle |
2 |
|
bottom emitting |
2 |
|
broadband absorption enhancement |
2 |
|
cathodoluminescence |
2 |
|
charge transfer |
2 |
|
chemical vapor deposition |
2 |
|
chemical vapour deposition (cvd) |
2 |
|
citrate sol-gel |
2 |
|
co-host |
2 |
|
coordination complexes - chemistry |
2 |
|
data storage equipment |
2 |
|
defect passivation |
2 |
|
detailed balance |
2 |
|
device configurations |
2 |
|
device model |
2 |
|
device performance |
2 |
|
device stability |
2 |
|
dielectric properties |
2 |
|
direct nanopatterning |
2 |
|
drift-diffusion |
2 |
|
drift-diffusion model |
2 |
|
efficiency |
2 |
|
efficiency improvement |
2 |
|
efficiency loss |
2 |
|
efficient scattering matrix method |
2 |
|
electrical effects |
2 |
|
electrical performance |
2 |
|
electron transport |
2 |
|
exciton delocalization |
2 |
|
exciton lifetime |
2 |
|
exciton quenching |
2 |
|
exciton transfer |
2 |
|
excitons |
2 |
|
exhibitions |
2 |
|
fast response |
2 |
|
fiber optics |
2 |
|
fibers |
2 |
|
fluorenes - chemistry |
2 |
|
fluorescence |
2 |
|
fullerenes - chemistry |
2 |
|
gdcaal3o7:re3+ (re=eu, tb) |
2 |
|
gold - chemistry |
2 |
|
gold nanoparticles |
2 |
|
gradient type |
2 |
|
gratings |
2 |
|
growth mechanism |
2 |
|
growth mechanisms |
2 |
|
high on/off ratio |
2 |
|
ii-vi semiconductor nanostructures |
2 |
|
intrinsic radiative recombination |
2 |
|
iridium - chemistry |
2 |
|
light out-coupling |
2 |
|
light trapping |
2 |
|
lighting systems |
2 |
|
localized surface plasmon resonance |
2 |
|
luminescence |
2 |
|
metal complexes |
2 |
|
metal nanoparticles - chemistry |
2 |
|
metallic nanoparticles |
2 |
|
metals |
2 |
|
metastable phase znse |
2 |
|
mobility |
2 |
|
nanobelts |
2 |
|
nanocrystals |
2 |
|
nanogratings |
2 |
|
nanoparticles |
2 |
|
nanorings |
2 |
|
nanostructures - chemistry |
2 |
|
nanowires |
2 |
|
nickel oxide |
2 |
|
operational stability |
2 |
|
optical and electrical properties |
2 |
|
optics |
2 |
|
organic chemicals - chemistry |
2 |
|
organic light emitting diodes |
2 |
|
organic light-emitting diodes (oleds) |
2 |
|
organic photodetectors |
2 |
|
organic solar cells |
2 |
|
passivation |
2 |
|
pdp green phosphors |
2 |
|
periodic nanostructures |
2 |
|
permittivity |
2 |
|
perovskite light-emitting diodes |
2 |
|
perovskite solar cells |
2 |
|
photo-electro-thermal (pet) theory |
2 |
|
photovoltaics |
2 |
|
plasmonic resonance |
2 |
|
plasmonic structures |
2 |
|
quantum theory |
2 |
|
scattering |
2 |
|
semiconductors |
2 |
|
shape-dependent plasmonic effect |
2 |
|
shift of light emission |
2 |
|
stability |
2 |
|
ternary organic solar cells |
2 |
|
titanates |
2 |
|
tris(8-hydroxyquinoline) aluminum |
2 |
|
ultraviolet |
2 |
|
wurtzite phase znse |
2 |
|
zno nanorods |
2 |
|
zno-znse |
2 |
|
znse |
2 |
|
znse grain |
2 |
|
β-cspbi 3 |
2 |
|
(fluoronaphthyl)thienyl |
1 |
|
2-mercaptobenzothiazole |
1 |
|
4-(2-aminoethyl) benzoic acid bromide |
1 |
|
78.65 |
1 |
|
81.60.cp |
1 |
|
82.50 |
1 |
|
a. inorganic compounds |
1 |
|
a. nanostructures |
1 |
|
a. optical materials |
1 |
|
absolute optical properties |
1 |
|
acousto-optic device |
1 |
|
acousto-optic devices |
1 |
|
acoustooptic device |
1 |
|
adsorption |
1 |
|
al/au electrode |
1 |
|
algaas/gaas quantum well |
1 |
|
alignment band structure |
1 |
|
alkyl side chain |
1 |
|
alkylammonium cations |
1 |
|
all-perovskite |
1 |
|
aluminum |
1 |
|
aluminum nanoclusters |
1 |
|
annealing temperatures |
1 |
|
au nps |
1 |
|
b. vapour deposition |
1 |
|
band alignments |
1 |
|
band gaps |
1 |
|
bipolar molecules |
1 |
|
blue light emission |
1 |
|
blue perovskite leds |
1 |
|
blue perovskite light-emitting diodes |
1 |
|
broad spectral photodetectors |
1 |
|
built-in electric field |
1 |
|
bulk-heterojunction solar cells |
1 |
|
capillary force |
1 |
|
carrier extraction |
1 |
|
carrier transport layer |
1 |
|
carrier transport layers |
1 |
|
carrier transport/injection layer |
1 |
|
carrier transportation and distribution |
1 |
|
cathode interfacial materials |
1 |
|
cerium ion |
1 |
|
ch3nh3cl |
1 |
|
ch3nh3pbi3 |
1 |
|
charge accumulation |
1 |
|
charge carrier transport |
1 |
|
chemical precipitation method |
1 |
|
chemical stability |
1 |
|
chemical treatment |
1 |
|
chemistry |
1 |
|
color-tuning |
1 |
|
complex solvent |
1 |
|
computers |
1 |
|
conjugated polymers |
1 |
|
continuous crystal |
1 |
|
contributing factor |
1 |
|
conventional methods |
1 |
|
convergent-beam electron diffraction |
1 |
|
crystallinity |
1 |
|
crystallization process |
1 |
|
cspbbr3 nanocrystals |
1 |
|
cspbi3 |
1 |
|
cuboid |
1 |
|
current conduction mechanism |
1 |
|
current-voltage hysteresis |
1 |
|
defect density |
1 |
|
depletion interactions |
1 |
|
detector |
1 |
|
diffused quantum well |
1 |
|
diffused quantum well (dfqw) |
1 |
|
diffusion process |
1 |
|
diketopyrrolopyrrole |
1 |
|
dimethyl sulfoxide |
1 |
|
dipole formation |
1 |
|
display application |
1 |
|
distributed feedback (dfb) lasers |
1 |
|
distributed feedback lasers |
1 |
|
dj 2d perovskites |
1 |
|
doping hole injection layer |
1 |
|
double emission layer |
1 |
|
double hole injection layer |
1 |
|
double quantum well |
1 |
|
driving forces |
1 |
|
dye |
1 |
|
efficiency enhancement |
1 |
|
efficiency roll-off |
1 |
|
efficient anode |
1 |
|
efficient graphene cathode |
1 |
|
efficient strategies |
1 |
|
electrical conductivity |
1 |
|
electrical properties |
1 |
|
electrical transport measurements |
1 |
|
electro-optical modulation |
1 |
|
electroabsorption |
1 |
|
electroabsorption modulation |
1 |
|
electrochemistry physics |
1 |
|
electrode quenching |
1 |
|
electrodes |
1 |
|
electroluminescence |
1 |
|
electroluminescent (el) decay mechanism |
1 |
|
electroluminescent (el) efficiency |
1 |
|
electron extraction |
1 |
|
electron holography |
1 |
|
electron transport layer |
1 |
|
electrooptic materials/devices |
1 |
|
electrooptic modulation |
1 |
|
electrooptical modulation |
1 |
|
electrostatic energies |
1 |
|
elemental selenium |
1 |
|
emission layers |
1 |
|
emission spectrums |
1 |
|
emission wavelength |
1 |
|
energy level alignment modulation |
1 |
|
energy transfer |
1 |
|
energy transferring |
1 |
|
environment friendly |
1 |
|
exciton formation |
1 |
|
experimental platform |
1 |
|
facile formation approach |
1 |
|
fill factor |
1 |
|
film formations |
1 |
|
flexible photovoltaics |
1 |
|
flexible pscs |
1 |
|
flexible solar cells |
1 |
|
flexible transparent electrodes |
1 |
|
fluorescent lamps |
1 |
|
fractional-order modeling |
1 |
|
full-color |
1 |
|
general method |
1 |
|
geometric parameter regulation |
1 |
|
gold nanocluster |
1 |
|
gradient structures |
1 |
|
grain boundaries |
1 |
|
grain boundary passivation |
1 |
|
graphene |
1 |
|
grating |
1 |
|
high colour purity |
1 |
|
high detectivity |
1 |
|
high field |
1 |
|
high luminance |
1 |
|
high optical transmission electrode |
1 |
|
high transmission |
1 |
|
high-vacuum evaporation |
1 |
|
hole collection |
1 |
|
hole injection layer |
1 |
|
hole transport layer |
1 |
|
hole transport layers |
1 |
|
hole transport material |
1 |
|
hole transport materials |
1 |
|
hole transports |
1 |
|
hole-transport layers |
1 |
|
hole-transporting layer |
1 |
|
hypocrystalline intermediate |
1 |
|
ideal model |
1 |
|
imidazole graphene quantum dots |
1 |
|
impedance spectroscopy |
1 |
|
improved hole injection |
1 |
|
in doped cucro2 |
1 |
|
indium-free interconnecting layer |
1 |
|
inorganic hole transport layer |
1 |
|
inorganic metal halide perovskite |
1 |
|
inorganic metal oxides |
1 |
|
inorganic perovskite |
1 |
|
instruments |
1 |
|
inter-grain element distributions |
1 |
|
interconnecting |
1 |
|
interconnecting layer |
1 |
|
interconnecting layers |
1 |
|
interface defects |
1 |
|
interface electron transport materials |
1 |
|
interface engineering |
1 |
|
interface layers |
1 |
|
interface modifications |
1 |
|
interface regulation |
1 |
|
interfacial contact |
1 |
|
interficial reaction |
1 |
|
intermediate electrode |
1 |
|
intermediate interconnecting layer |
1 |
|
intermixing quantum well |
1 |
|
inverted perovskite solar cells |
1 |
|
inverted planar perovskite solar cells |
1 |
|
ion mobilization |
1 |
|
ionic liquids |
1 |
|
key factors |
1 |
|
large-area applications |
1 |
|
ligand exchange |
1 |
|
ligand spacers |
1 |
|
ligands |
1 |
|
light absorption enhancement |
1 |
|
light emission |
1 |
|
light emitting devices |
1 |
|
light extraction efficiency |
1 |
|
light management |
1 |
|
light-emitting device |
1 |
|
light-emitting electrochemical cells |
1 |
|
liquid additives |
1 |
|
low boiling point solvent |
1 |
|
low dark current |
1 |
|
low noise currents |
1 |
|
low temperature |
1 |
|
low temperature annealing |
1 |
|
low-band-gap perovskites |
1 |
|
low-bandgap |
1 |
|
low-bandgap sn-rich perovskites |
1 |
|
low-bandgap sn–pb perovskites |
1 |
|
low-temperature space-restricted crystallization |
1 |
|
low‐temperature substrates |
1 |
|
luminance |
1 |
|
maghemite and iron hydroxide |
1 |
|
magnetic field strengths |
1 |
|
mapbbr3 hybrid perovskite |
1 |
|
metal electrodes |
1 |
|
metal halide perovskites |
1 |
|
metal oxides |
1 |
|
metal oxides carrier transport layers |
1 |
|
metallophthalocyanines |
1 |
|
methylamine |
1 |
|
microcavities |
1 |
|
microcavity |
1 |
|
microcavity structures |
1 |
|
mixed pb‐sn perovskite solar cells |
1 |
|
mixing gibbs free energy |
1 |
|
mixing ratios |
1 |
|
modeling |
1 |
|
modification of quantum well |
1 |
|
modulators |
1 |
|
monolithic all-perovskite tandem solar cells |
1 |
|
morphology control |
1 |
|
mxenes |
1 |
|
n |
1 |
|
n-butylamine |
1 |
|
nano-network |
1 |
|
nanocomposite |
1 |
|
nanocrystal |
1 |
|
nanospacers |
1 |
|
nanostar |
1 |
|
nanostructure |
1 |
|
nanostructure coupling systems |
1 |
|
near-infrared imaging |
1 |
|
near-infrared photodetectors |
1 |
|
nio x redox reaction |
1 |
|
niox |
1 |
|
niox nanostructure |
1 |
|
non-fullerene solar cells |
1 |
|
nonimmersive sintering |
1 |
|
normal and inverted device architectures |
1 |
|
optical amplifiers |
1 |
|
optical confinement of saw devices |
1 |
|
optical engineering |
1 |
|
optical losses |
1 |
|
optical materials/devices |
1 |
|
optical planar waveguides |
1 |
|
optical polarization |
1 |
|
optimization |
1 |
|
optoelectronics |
1 |
|
organic active layers |
1 |
|
organic leds |
1 |
|
organic light emission devices |
1 |
|
organic light emitting devices |
1 |
|
organic light-emitting devices |
1 |
|
organic light-emitting devices (oleds) |
1 |
|
organic light-emitting diodes |
1 |
|
organic lighting-emitting devices |
1 |
|
organic optoelectronic devices |
1 |
|
organic optoelectronics |
1 |
|
organic photovoltaics |
1 |
|
organic small molecules |
1 |
|
organic-inorganic halide perovskites |
1 |
|
orientation |
1 |
|
oxadiazole |
1 |
|
oxygen vacancies |
1 |
|
p-type semiconducting polymer |
1 |
|
patterned back electrodes |
1 |
|
pbi2 |
1 |
|
pbi6 octahedra anchors |
1 |
|
pbs quantum dots (qds) |
1 |
|
pedot: pss |
1 |
|
perfluorinated ionomer |
1 |
|
perovskite |
1 |
|
perovskite crystallization |
1 |
|
perovskite films |
1 |
|
perovskite heterostructures |
1 |
|
perovskite layers perovskite materials |
1 |
|
perovskite nanocrystals |
1 |
|
perovskite photodetectors |
1 |
|
phase stability |
1 |
|
phenanthroline |
1 |
|
phosphine oxide |
1 |
|
phosphor |
1 |
|
phosphors |
1 |
|
photodetector |
1 |
|
photodetectors |
1 |
|
photodiodes |
1 |
|
photon lifetime |
1 |
|
photovoltaic photodetectors |
1 |
|
physics engineerning chemistry |
1 |
|
piezoelectric effect of saw |
1 |
|
piezoelectric effect of surface acoustic wave |
1 |
|
piezoelectric effect of surface acoustic waves |
1 |
|
planar perovskite solar cells |
1 |
|
plasmon-electrical |
1 |
|
plasmon-induced chemical reaction |
1 |
|
plasmon-optical |
1 |
|
plasmonic asymmetric modes |
1 |
|
plasmonic enhancement |
1 |
|
pleds |
1 |
|
polarization independence |
1 |
|
poly(styrene sulfonate) |
1 |
|
polymer chains |
1 |
|
polymer/organic solar cells |
1 |
|
post-treatment-free |
1 |
|
potassium thiocyanate |
1 |
|
power conversion efficiencies |
1 |
|
power efficiency |
1 |
|
pre-treatment-free |
1 |
|
processing issues |
1 |
|
pyridine |
1 |
|
quantum dots |
1 |
|
quantum well modulator |
1 |
|
quantum wells |
1 |
|
quantum-confined stark effect |
1 |
|
quantum-well devices |
1 |
|
quantum-well interdiffusion |
1 |
|
quantum-well intermixing |
1 |
|
quantum-well optical amplifier |
1 |
|
quantumconfined stark effect |
1 |
|
quasi-2d perovskites |
1 |
|
quasi-3d nanocomposite |
1 |
|
quasi‐2d perovskite |
1 |
|
quasi‐core–shell structures |
1 |
|
rare-earth (re) organic light-emitting diodes (oleds) |
1 |
|
real-time color tuning |
1 |
|
reduced driving voltage |
1 |
|
rigidity |
1 |
|
rigorous electromagnetic approach |
1 |
|
room temperature |
1 |
|
room temperature production |
1 |
|
room-temperature crystallization |
1 |
|
room-temperature nanoimprint |
1 |
|
room-temperature solution process |
1 |
|
rubidium incorporation |
1 |
|
s-shape |
1 |
|
scanning and transmission electron microscopy |
1 |
|
selenium compounds - chemistry |
1 |
|
self-assembly film formation |
1 |
|
semi-transparent devices |
1 |
|
semiconductor doping |
1 |
|
semiconductor waveguides |
1 |
|
sequential deposition |
1 |
|
silica |
1 |
|
silver nanonetworks |
1 |
|
silver nanoparticles |
1 |
|
silver nanowires |
1 |
|
single crystal |
1 |
|
single crystals |
1 |
|
sky-blue perovskite light-emitting diodes |
1 |
|
small molecule |
1 |
|
sn–pb perovskites |
1 |
|
sn−pb-based perovskites |
1 |
|
snpb perovskites |
1 |
|
sol-gel processes |
1 |
|
solid electrolytes |
1 |
|
solid–liquid phase separation |
1 |
|
solution process |
1 |
|
solution processability |
1 |
|
solution processable |
1 |
|
solution-processed self-assembly method |
1 |
|
solvent engineering |
1 |
|
solvent resistance |
1 |
|
solvothermal synthesis |
1 |
|
stacked oleds |
1 |
|
stacked organic light-emitting devices (soleds) |
1 |
|
strain layered material |
1 |
|
structure-property relationships |
1 |
|
sulfides - chemistry |
1 |
|
surface acoustic wave |
1 |
|
surface acoustic wave modulator |
1 |
|
surface enhanced raman scattering |
1 |
|
surface self‐assembly monolayer |
1 |
|
surface-acoustic-wave modulator |
1 |
|
tandem |
1 |
|
tandem devices |
1 |
|
tandem organic solar cell |
1 |
|
tandem solar cells |
1 |
|
ternary metal oxide nanoparticles |
1 |
|
ternary oxides |
1 |
|
theoretical result |
1 |
|
thermionic emission |
1 |
|
thick perovskites |
1 |
|
thiophenol ligands |
1 |
|
titanium dioxide |
1 |
|
titanium oxide |
1 |
|
top electrode |
1 |
|
transient photocurrent |
1 |
|
transient photovoltage |
1 |
|
transition metal oxide |
1 |
|
transition metal oxides |
1 |
|
transparent anode |
1 |
|
transparent electrode |
1 |
|
transparent front electrodes |
1 |
|
triazolium ionic liquids |
1 |
|
triphenylamine |
1 |
|
triple interface passivation |
1 |
|
tris (8-hydroxyquinoline) aluminum |
1 |
|
tunable devices |
1 |
|
tunable work function |
1 |
|
tungsten compounds |
1 |
|
turn‐on voltage |
1 |
|
two-dimensional like polymers |
1 |
|
ultra-thin au |
1 |
|
ultrasmall |
1 |
|
ultrathin metal films |
1 |
|
ultraviolet photoemission spectroscopy |
1 |
|
ultraviolet–visible–near infrared detection |
1 |
|
upside-down method |
1 |
|
uv-ozone |
1 |
|
vacuum ultraviolet |
1 |
|
vacuum-assisted thermal annealing |
1 |
|
visible light |
1 |
|
wavelength tuning |
1 |
|
white light-emitting diode |
1 |
|
wide-bandgap copolymers |
1 |
|
x-ray detector |
1 |
|
x-ray detectors |
1 |
|
zinc - chemistry |
1 |
|
zinc compounds - chemistry |
1 |
