1.
Cesium Doped NiOx as an Efficient Hole Extraction Layer for Invert..
[1057]
|
2.
Inverted perovskite solar cells using dimethylacridine-based dopan..
[711]
|
3.
Monolithic perovskite/organic tandem solar cells with 23.6% effici..
[569]
|
4.
Heterogeneous 2D/3D Tin-Halides Perovskite Solar Cells with Certif..
[556]
|
5.
Large Stokes Shift and High Efficiency Luminescent Solar Concentra..
[269]
|
6.
Low temperature processed, high-performance and stable NiOx based ..
[253]
|
7.
Strong band filling induced significant excited state absorption i..
[234]
|
8.
Enhanced efficiency and stability in Sn-based perovskite solar cel..
[224]
|
9.
Stabilizing n-Type hetero-junctions for NiO: X based inverted plan..
[203]
|
10.
High Short-Circuit Current Density via Integrating the Perovskite ..
[182]
|
11.
Dopant-Free Small-Molecule Hole-Transporting Material for Inverted..
[181]
|
12.
Teaching an Old Anchoring Group New Tricks: Enabling Low-Cost, Eco..
[176]
|
13.
Photon-generated carriers excite superoxide species inducing long-..
[175]
|
14.
Defining the composition and electronic structure of large-scale a..
[175]
|
15.
Interfacial stabilization for inverted perovskite solar cells with..
[175]
|
16.
Formamidinium-Based Lead Halide Perovskites: Structure, Properties..
[174]
|
17.
Degradation induced lattice anchoring self-passivation in CsPbI3-x..
[174]
|
18.
N-type conjugated polymer as efficient electron transport layer fo..
[166]
|
19.
Engineering of dendritic dopant-free hole transport molecules: ena..
[165]
|
20.
Interfacial-Field-Induced Increase of the Structural Phase Transit..
[159]
|
21.
An Efficient and Effective Design of InP Nanowires for Maximal Sol..
[159]
|
22.
Mixed Spacer Cation Stabilization of Blue-Emitting n = 2 Ruddlesde..
[150]
|
23.
Dopant-Free Hole Transporting Molecules for Highly Efficient Perov..
[146]
|
24.
Improving Efficiency and Stability of Perovskite Solar Cells Enabl..
[143]
|
25.
A critical review on bismuth and antimony halide based perovskites..
[143]
|
26.
Sputtered Indium-Zinc Oxide for Buffer Layer Free Semitransparent ..
[140]
|
27.
Backbone Coplanarity Tuning of 1,4-Di(3-alkoxy-2-thienyl)-2,5-difl..
[139]
|
28.
Novel Molecular Doping Mechanism for n-Doping of SnO2 via Tripheny..
[139]
|
29.
Molecule-Doped Nickel Oxide: Verified Charge Transfer and Planar I..
[138]
|
30.
Side-Chain Engineering of Donor-Acceptor Conjugated Small Molecule..
[136]
|
31.
Alkali Chlorides for the Suppression of the Interfacial Recombinat..
[133]
|
32.
High-Performance Semitransparent and Bifacial Perovskite Solar Cel..
[132]
|
33.
Conjugated Polymer-Assisted Grain Boundary Passivation for Efficie..
[131]
|
34.
Influence of mixed organic cations on the structural and optical p..
[126]
|
35.
Investigation on the role of amines in the liquefaction and recrys..
[126]
|
36.
Self-Powered and Broadband Lead-Free Inorganic Perovskite Photodet..
[125]
|
37.
Understanding the Doping Effect on NiO: Toward High-Performance In..
[124]
|
38.
Efficient Perovskite Solar Cells with a Novel Aggregation-Induced ..
[124]
|
39.
Imide-functionalized acceptor-acceptor copolymers as efficient ele..
[122]
|
40.
Crystalline and magnetic structures, magnetization, heat capacity,..
[120]
|
41.
Synergy Effect of Both 2,2,2-Trifluoroethylamine Hydrochloride and..
[119]
|
42.
Impact and Origin of Interface States in MOS Capacitor with Monola..
[114]
|
43.
Efficient planar antimony sulfide thin film photovoltaics with lar..
[113]
|
44.
Understanding the Impact of Cu-In-Ga-S Nanoparticles Compactness o..
[112]
|
45.
The Impact of Hybrid Compositional Film/Structure on Organic-Inorg..
[111]
|
46.
A novel volumetric absorber integrated with low-cost D-Mannitol an..
[111]
|
47.
Efficient and Stable FASnI(3) Perovskite Solar Cells with Effectiv..
[109]
|
48.
Oxygen pressure influence on properties of nanocrystalline linbo3 ..
[109]
|
49.
Metal oxide charge transport layers in perovskite solar cells-opti..
[109]
|
50.
The Non-Innocent Role of Hole-Transporting Materials in Perovskite..
[108]
|
51.
Tin-Based Defects and Passivation Strategies in Tin-Related Perovs..
[107]
|
52.
Alloy-induced phase transition and enhanced photovoltaic performan..
[106]
|
53.
Charge-transfer induced multifunctional BCP:Ag complexes for semi-..
[106]
|
54.
Efficient and stable TiO2/Sb2S3 planar solar cells from absorber c..
[105]
|
55.
Piezoelectric energy harvester based on LiNbO3 thin films
[105]
|
56.
Stability of perovskite solar cells on flexible substrates
[104]
|
57.
Promising ITO-free perovskite solar cells with WO3-Ag-SnO2 as tran..
[103]
|
58.
Multifunctional atomic force probes for Mn2+ doped perovskite sola..
[100]
|
59.
Coupling halide perovskites with different materials: From doping ..
[100]
|
60.
Printable Fabrication of a Fully Integrated and Self-Powered Senso..
[98]
|
61.
A low-temperature-annealed and UV-ozone-enhanced combustion derive..
[97]
|
62.
Monolayer WxMo1-xS2 Grown by Atmospheric Pressure Chemical Vapor D..
[95]
|
63.
Black Phosphorus Based Field Effect Transistors with Simultaneousl..
[94]
|
64.
Synthesis of Lead-Free Perovskite Films by Combinatorial Evaporati..
[93]
|
65.
Thermal and Thermochemical Energy Conversion and Storage
[93]
|
66.
Metal Acetylacetonate Series in Interface Engineering for Full Low..
[90]
|
67.
System performance and economic assessment of a thermal energy sto..
[90]
|
68.
Oriented Crystallization of Mixed-Cation Tin Halides for Highly Ef..
[90]
|
69.
Supersmooth Ta2O5/Ag/Polyetherimide Film as the Rear Transparent E..
[86]
|
70.
光生载流子激发的超氧根离子对甲胺钙钛矿晶体光致荧光增强的作用机制
[86]
|
71.
General Method To Define the Type of Carrier Transport Materials f..
[85]
|
72.
Ruthenium acetylacetonate in interface engineering for high perfor..
[85]
|
73.
Close-loop recycling of perovskite solar cells through dissolution..
[84]
|
74.
High-temperature magnetism and crystallography of a YCrO3 single c..
[83]
|
75.
Enhancing the Efficiency and Stability of NiOx-Based Silicon Photo..
[82]
|
76.
Efficient planar antimony sulfide thin film photovoltaics with lar..
[82]
|
77.
甲胺钙钛矿晶体光致荧光增强作用机制:光生载流子激发的超氧根离子对表..
[80]
|
78.
Black Phosphorus Quantum Dots for Hole Extraction of Typical Plana..
[79]
|
79.
Band alignment of HfO2/multilayer MoS2 interface determined by x-r..
[78]
|
80.
High Short-Circuit Current Density via Integrating the Perovskite ..
[77]
|
81.
Low temperature carrier transport study of monolayer MoS2 field ef..
[76]
|
82.
Dialkylamines Driven Two-Step Recovery of NiOx/ITO Substrates for ..
[76]
|
83.
Tungsten-based highly selective solar absorber using simple nanodi..
[75]
|
84.
A weak Galerkin method for diffraction gratings
[75]
|
85.
Robust interface engineering for high-performance and stable inver..
[75]
|
86.
Band alignment of atomic layer deposited high-k Al2O3/multilayer M..
[73]
|
87.
Moth eye-inspired highly efficient, robust, and neutral-colored se..
[73]
|
88.
Bathocuproine:Ag Complex Functionalized Tunneling Junction for Eff..
[72]
|
89.
Broadband Polarization-Insensitive Absorption In Solar Spectrum En..
[70]
|
90.
Inverted planar organic-inorganic hybrid perovskite solar cells wi..
[70]
|
91.
Band alignment of ZnO/multilayer MoS2 interface determined by x-ra..
[69]
|
92.
Wide-Range Tunable Fluorescence Lifetime and Ultrabright Luminesce..
[68]
|
93.
Vertical Heterogeneous Integration of Metal Halide Perovskite Quan..
[68]
|
94.
Perovskite solar cells - An overview of critical issues
[67]
|
95.
Large-scale planar and spherical light-emitting diodes based on ar..
[67]
|
96.
High transmittance inorganic semiconductors as a hole-transport wi..
[65]
|
97.
Low Cost and Solution Processed Interfacial Layer Based on Poly(2-..
[65]
|
98.
Near-perfect absorber of infrared radiation based on Au nanorod ar..
[64]
|
99.
Black phosphorus transistors with enhanced hole transport and subt..
[62]
|
100.
Black Phosphorus Transistors with Enhanced Hole Transport and Subt..
[56]
|