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Efficient bifacial semi-transparent perovskite solar cells via a dimethylformamide-free solvent and bandgap engineering strategy

Authors
 Han, E. q  ;  Yun, Jung-Ho  ;  Maeng, Inhee  ;  Qiu, Tengfei  ;  Zhang, Yurou  ;  Choi, Eunyoung  ;  Lee, Su-Min  ;  Chen, Peng  ;  Hao, Mengmeng  ;  Yang, Yang  ;  Wang, Hongxia  ;  Zhang, Bo Wei  ;  Yun, Jae Sung  ;  Seidel, Jan  ;  Lyu, Miaoqiang  ;  Wang, Lianzhou 
Citation
 NANO ENERGY, Vol.131, 2024-12 
Article Number
 110136 
Journal Title
 NANO ENERGY 
ISSN
 2211-2855 
Issue Date
2024-12
Keywords
Semi-transparent perovskite solar cell ; Dimethylformamide free ; Indoor solar cell ; Bifacial photovoltaics ; Bandgap engineering
Abstract
Semi-transparent perovskite solar cells (ST-PSCs) featuring high performance and light transmittance are highly desirable for building integrated photovoltaic (BIPV) applications. However, it is challenging to balance the device efficiency and transmittance due to the trade-off between light-harvesting capability and transparency of the perovskite active layer. Herein, we demonstrate a simple solvent- and bandgap-engineering strategy to effectively enhance film transparency of (FAPbI(3))(0.85)(MAPbBr(3))(0.15) perovskite while simultaneously preserving its decent light-harvesting capability. N-methyl-2-pyrrolidone (NMP) as the solvent of the perovskite precursor effectively confines the growth of perovskite grains, leading to reduced light-scattering and enhanced average visible transparency (AVT) of the perovskite layer (over 28 %). Meanwhile, the NMP solvent promotes the growth of highly crystalline perovskite films with excellent light-harvesting capability, largely benefiting from stable intermediate adducts due to its intrinsic nature as a coordinative Lewis base. Further bandgap engineering of the perovskite light adsorber (1.6 eV) leads to the design of highly efficient bifacial ST-PSCs, achieving a power conversion efficiency of 15.58 % when illuminated from the conductive glass side and 9.67 % from the top electrode side, both under 1 sun illumination. The best-performing devices also show great promise for indoor applications with an efficiency of 25 % under 1000 lux indoor light illumination.
DOI
10.1016/j.nanoen.2024.110136
Appears in Collections:
1. College of Medicine (의과대학) > Research Institute (부설연구소) > 1. Journal Papers
Yonsei Authors
Maeng, In hee(맹인희)
URI
https://ir.ymlib.yonsei.ac.kr/handle/22282913/202239
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