| 1.
Hybrid Perovskite Light-Emitting Diodes Based on Perovskite Nanocr..
[565]
|
| 2.
Beyond OLED: Efficient Quantum Dot Light-Emitting Diodes for Displ..
[386]
|
| 3.
Improving blue quantum dot light-emitting diodes by a lithium fluo..
[344]
|
| 4.
Defects Passivation With Dithienobenzodithiophene-based pi-conjuga..
[253]
|
| 5.
Alternating-current driven quantum-dot light-emitting diodes with ..
[244]
|
| 6.
Investigation on Thermally Induced Efficiency Roll-Off: Toward Eff..
[225]
|
| 7.
High efficiency FAPbBr3 perovskite light-emitting diode
[204]
|
| 8.
Less-Lead Control toward Highly Efficient Formamidinium-Based Pero..
[203]
|
| 9.
Stabilizing n-Type hetero-junctions for NiO: X based inverted plan..
[203]
|
| 10.
Electric Bias Induced Degradation in Organic-Inorganic Hybrid Pero..
[193]
|
| 11.
A very dark-and-conductive electrode based on Mo/MoOx/ITO structur..
[186]
|
| 12.
High performance top-emitting quantum dot light-emitting diodes wi..
[182]
|
| 13.
Halide-Rich Synthesized Cesium Lead Bromide Perovskite Nanocrystal..
[178]
|
| 14.
Enhanced conductivity of transparent and. flexible silver nanowire..
[177]
|
| 15.
Thin film perovskite light-emitting diode based on CsPbBr3 powders..
[174]
|
| 16.
Erratum: Tetrafluorinated phenylpyridine based heteroleptic iridiu..
[171]
|
| 17.
Tetrafluorinated phenylpyridine based heteroleptic iridium(iii) co..
[170]
|
| 18.
Plasmonic Perovskite Light-Emitting Diodes Based on the Ag-CsPbBr3..
[142]
|
| 19.
A simple and efficient approach toward deep-red to near-infrared-e..
[134]
|
| 20.
Improving Electron Mobility of Tetraphenylethene-Based AlEgens to ..
[133]
|
| 21.
Iridium(III) complexes with 1-phenylisoquinoline-4-carbonitrile un..
[127]
|
| 22.
Recent progress in the device architecture of white quantum-dot li..
[126]
|
| 23.
New carbazole-substituted siloles for the fabrication of efficient..
[123]
|
| 24.
Understanding the Interplay of Binary Organic Spacer in Ruddlesden..
[121]
|
| 25.
The synthesis, crystal structures, aggregation-induced emission an..
[116]
|
| 26.
Tuning the AIE Activities and Emission Wavelengths of Tetraphenyle..
[116]
|
| 27.
Achieving High-Performance Solution-Processed Deep-Red/Near-Infrar..
[107]
|
| 28.
Tetraphenylbenzosilole: An AIE Building Block for Deep-Blue Emitte..
[107]
|
| 29.
Origin of Positive Aging in Quantum-Dot Light-Emitting Diodes
[105]
|
| 30.
Blue OLEDs with narrow bandwidth using CF3 substituted bis((carbaz..
[103]
|
| 31.
Investigation of Exciton Recombination Zone in Quantum Dot Light-E..
[102]
|
| 32.
High throughput screening of novel tribromide perovskite materials..
[102]
|
| 33.
Hydrophobic Cu2O Quantum Dots Enabled by Surfactant Modification a..
[100]
|
| 34.
Fabrication of color tunable organic light-emitting diodes by an a..
[100]
|
| 35.
New phosphorescent iridium(iii) dipyrrinato complexes: synthesis, ..
[100]
|
| 36.
Improved Efficiency and Enhanced Color Quality of Light-Emitting D..
[99]
|
| 37.
A low-temperature-annealed and UV-ozone-enhanced combustion derive..
[98]
|
| 38.
Construction of two AIE luminogens comprised of a tetra-/tri-pheny..
[98]
|
| 39.
Over 100 cd A(-1) Efficient Quantum Dot Light-Emitting Diodes with..
[98]
|
| 40.
Flexible and tandem quantum-dot light-emitting diodes with individ..
[97]
|
| 41.
Efficient and Color Stable White Quantum-Dot Light-Emitting Diodes..
[96]
|
| 42.
Two novel phenylethene-carbazole derivatives containing dimesitylb..
[96]
|
| 43.
Optimizing the balance of holes and electrons in inverted quantum ..
[96]
|
| 44.
Efficient Red/Green/Blue Tandem Quantum-Dot Light-Emitting Diodes ..
[93]
|
| 45.
Aggregation-Induced Delayed Fluorescence Luminogens for Efficient ..
[92]
|
| 46.
Full color quantum dot light-emitting diodes patterned by photolit..
[92]
|
| 47.
ZnSe:Te/ZnSeS/ZnS nanocrystals: an access to cadmium-free pure-blu..
[92]
|
| 48.
Rational design of high efficiency green to deep red/near-infrared..
[91]
|
| 49.
Sky-blue nondoped OLEDs based on new AIEgens: ultrahigh brightness..
[90]
|
| 50.
High Performance NIR OLEDs with Emission Peak Beyond 760 nm and M..
[90]
|
| 51.
Quantum-dot and organic hybrid tandem light-emitting diodes with c..
[88]
|
| 52.
High efficiency FAPbBr3 perovskite light-emitting diode
[88]
|
| 53.
Organic light-emitting diodes fabricated on nanostructured AZO: A ..
[87]
|
| 54.
An ZnMgO: PVP inorganic- organic hybrid electron transport layer: ..
[86]
|
| 55.
Bright and efficient light-emitting diodes based on MA/Cs double c..
[86]
|
| 56.
Highly Luminescent CsPbBr3@Cs4PbBr6Nanocrystals and Their Applicat..
[86]
|
| 57.
Near-infrared and visible light dual-mode organic photodetectors
[85]
|
| 58.
Cadmium-Doped Zinc Sulfide Shell as a Hole Injection Springboard f..
[85]
|
| 59.
High efficiency FAPbBr3 perovskite light-emitting diode
[85]
|
| 60.
Selective wetting/dewetting for controllable patterning of liquid ..
[84]
|
| 61.
Solution-processed vanadium oxide as an efficient hole injection l..
[84]
|
| 62.
Suppressing Förster Resonance Energy Transfer in Close-Packed Qua..
[83]
|
| 63.
基于聚合物-量子点共混的量子点发光二极管
[83]
|
| 64.
Smart Design on the Cyclometalated Ligands of Iridium(III) Complex..
[82]
|
| 65.
All solution-processed white quantum-dot light-emitting diodes wit..
[81]
|
| 66.
Efficient vacuum-free-processed quantum dot light emitting diodes ..
[81]
|
| 67.
Platinum(II) cyclometallates featuring broad emission bands and th..
[81]
|
| 68.
Efficient quantum dot light-emitting diodes with a Zn0.85Mg0.15O i..
[80]
|
| 69.
3,4-Donor- and 2,5-acceptor-functionalized dipolar siloles: synthe..
[79]
|
| 70.
Aggregation-enhanced emission and through-space conjugation of tet..
[79]
|
| 71.
Quantum-dot and organic hybrid tandem light-emitting diodes with m..
[79]
|
| 72.
Ultrahigh Resolution Pixelated Top-Emitting Quantum-Dot Light-Emit..
[79]
|
| 73.
Synthesis, aggregation-induced emission and electroluminescence pr..
[78]
|
| 74.
A Low-Cost Nano-modified Substrate Integrating both Internal and E..
[78]
|
| 75.
The synthesis of novel AIE emitters with the triphenylethene-carba..
[77]
|
| 76.
High-Performance CsPb1-xSnxBr3 Perovskite Quantum Dots for Light-E..
[76]
|
| 77.
Nanocrystallized Organic Thin Films as Effective Light Outcoupling..
[76]
|
| 78.
Thermally activated delayed fluorescence material with aggregation..
[75]
|
| 79.
Efficient light-emitting diodes based on green perovskite nanocrys..
[75]
|
| 80.
Photo-/electro-luminescence enhancement of CsPbX3 (X = Cl, Br, or ..
[75]
|
| 81.
High efficiency FAPbBr3 perovskite light-emitting diode
[75]
|
| 82.
The influence of the hole transport layers on the performance of b..
[74]
|
| 83.
High-Performance Quantum Dot Light-Emitting Diodes Based on Al-Dop..
[74]
|
| 84.
Dimesitylboryl-functionalized tetraphenylethene derivatives: effic..
[74]
|
| 85.
Top-emitting quantum-dot light-emitting diodes with all the p-i-n ..
[74]
|
| 86.
Efficient red AIEgens based on tetraphenylethene: synthesis, struc..
[73]
|
| 87.
Steric, conjugation and electronic impacts on the photoluminescenc..
[73]
|
| 88.
Top-emitting organic light-emitting diodes integrated with thermal..
[73]
|
| 89.
Thermal assisted up-conversion electroluminescence in quantum dot ..
[73]
|
| 90.
Enhancing the Performance of Quantum-Dot Light-Emitting Diodes by ..
[72]
|
| 91.
Hybrid analog-digital driving method for high definition AMOLED
[71]
|
| 92.
High efficiency FAPbBr3 perovskite light-emitting diode
[71]
|
| 93.
Synthesis, aggregation-induced emission and electroluminescence pr..
[70]
|
| 94.
High-efficiency organic electroluminescent materials based on the ..
[70]
|
| 95.
Influence of Light-Matter Interaction on Efficiency of Quantum-Dot..
[70]
|
| 96.
Universal Bipolar Host Materials for Blue, Green, and Red Phosphor..
[69]
|
| 97.
Synthesis, aggregation-induced emission, and electroluminescence p..
[69]
|
| 98.
High-contrast top-emitting organic light-emitting diodes with AlO1..
[68]
|
| 99.
Flexible high energy density zinc-ion batteries enabled by binder-..
[68]
|
| 100.
A Pure Blue Phosphorescent Organic Light-Emitting Diode with an Ex..
[68]
|
