Application of microporous polyaniline counter electrode for dye-sensitized solar cells Q Li, J Wu, Q Tang, Z Lan, P Li, J Lin, L Fan Electrochemistry Communications 10 (9), 1299-1302, 2008 | 562 | 2008 |
High‐purity inorganic perovskite films for solar cells with 9.72% efficiency J Duan, Y Zhao, B He, Q Tang Angewandte chemie international edition 57 (14), 3787-3791, 2018 | 503 | 2018 |
Lanthanide Ions Doped CsPbBr3 Halides for HTM‐Free 10.14%‐Efficiency Inorganic Perovskite Solar Cell with an Ultrahigh Open‐Circuit Voltage of 1.594 V J Duan, Y Zhao, X Yang, Y Wang, B He, Q Tang Advanced Energy Materials 8 (31), 1802346, 2018 | 430 | 2018 |
The main progress of perovskite solar cells in 2020–2021 T Wu, Z Qin, Y Wang, Y Wu, W Chen, S Zhang, M Cai, S Dai, J Zhang, ... Nano-Micro Letters 13, 1-18, 2021 | 338 | 2021 |
Transparent metal selenide alloy counter electrodes for high‐efficiency bifacial dye‐sensitized solar cells Y Duan, Q Tang, J Liu, B He, L Yu Angewandte chemie international edition 53 (52), 14569-14574, 2014 | 269 | 2014 |
Platinum‐free binary Co‐Ni alloy counter electrodes for efficient dye‐sensitized solar cells X Chen, Q Tang, B He, L Lin, L Yu Angewandte Chemie 126 (40), 10975-10979, 2014 | 238 | 2014 |
Bifacial dye-sensitized solar cells: A strategy to enhance overall efficiency based on transparent polyaniline electrode J Wu, Y Li, Q Tang, G Yue, J Lin, M Huang, L Meng Scientific reports 4 (1), 4028, 2014 | 218 | 2014 |
Dissolution engineering of platinum alloy counter electrodes in dye‐sensitized solar cells Q Tang, H Zhang, Y Meng, B He, L Yu Angewandte Chemie International Edition 54 (39), 11448-11452, 2015 | 203 | 2015 |
Interfacial Strain Release from the WS2/CsPbBr3 van der Waals Heterostructure for 1.7 V Voltage All‐Inorganic Perovskite Solar Cells Q Zhou, J Duan, X Yang, Y Duan, Q Tang Angewandte Chemie 132 (49), 22181-22185, 2020 | 201 | 2020 |
All-inorganic CsPbBr 3 perovskite solar cell with 10.26% efficiency by spectra engineering H Yuan, Y Zhao, J Duan, Y Wang, X Yang, Q Tang Journal of materials chemistry A 6 (47), 24324-24329, 2018 | 194 | 2018 |
A highly efficient TiO 2@ ZnO n–p–n heterojunction nanorod photocatalyst L Lin, Y Yang, L Men, X Wang, D He, Y Chai, B Zhao, S Ghoshroy, Q Tang Nanoscale 5 (2), 588-593, 2013 | 191 | 2013 |
Tailored Lattice “Tape” to Confine Tensile Interface for 11.08%‐Efficiency All‐Inorganic CsPbBr3 Perovskite Solar Cell with an Ultrahigh Voltage of 1.702 V Q Zhou, J Duan, J Du, Q Guo, Q Zhang, X Yang, Y Duan, Q Tang Advanced Science 8 (19), 2101418, 2021 | 188 | 2021 |
Recent advances in critical materials for quantum dot-sensitized solar cells: a review J Duan, H Zhang, Q Tang, B He, L Yu Journal of Materials Chemistry A 3 (34), 17497-17510, 2015 | 181 | 2015 |
Review on recent progress of lead-free halide perovskites in optoelectronic applications J Li, J Duan, X Yang, Y Duan, P Yang, Q Tang Nano Energy 80, 105526, 2021 | 177 | 2021 |
Rapid conversion from carbohydrates to large-scale carbon quantum dots for all-weather solar cells Q Tang, W Zhu, B He, P Yang ACS nano 11 (2), 1540-1547, 2017 | 170 | 2017 |
Inorganic perovskite solar cells: an emerging member of the photovoltaic community J Duan, H Xu, WEI Sha, Y Zhao, Y Wang, X Yang, Q Tang Journal of Materials Chemistry A 7 (37), 21036-21068, 2019 | 166 | 2019 |
Lattice Modulation of Alkali Metal Cations Doped Cs1−xRxPbBr3 Halides for Inorganic Perovskite Solar Cells Y Li, J Duan, H Yuan, Y Zhao, B He, Q Tang Solar RRL 2 (10), 1800164, 2018 | 164 | 2018 |
A large‐area light‐weight dye‐sensitized solar cell based on all titanium substrates with an efficiency of 6.69% outdoors J Wu, Y Xiao, Q Tang, G Yue, J Lin, M Huang, Y Huang, L Fan, Z Lan, ... Advanced Materials 24 (14), 1884-1888, 2012 | 161 | 2012 |
Counter electrodes from double-layered polyaniline nanostructures for dye-sensitized solar cell applications Q Tang, H Cai, S Yuan, X Wang Journal of materials chemistry A 1 (2), 317-323, 2013 | 156 | 2013 |
Enhancement of the photovoltaic performance of dye-sensitized solar cells by doping Y {sub 0.78} Yb {sub 0.20} Er {sub 0.02} F {sub 3} in the photoanode J Wu, J Wang, J Lin, Z Lan, Q Tang, M Huang, Y Huang, L Fan, Q Li, ... Advanced Energy Materials 2, 2012 | 148 | 2012 |