Surface heterojunction based on n-type low-dimensional perovskite film for highly efficient perovskite tandem solar cells

Enhancing the quality of junctions is crucial for optimizing carrier extraction and suppressing recombination in semiconductor devices. In recent years, metal halide perovskite has emerged as the most promising next-generation material for optoelectronic devices. However, the construction of high-qu...

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Published inNational science review Vol. 11; no. 5; p. nwae055
Main Authors Jiang, Xianyuan, Zhou, Qilin, Lu, Yue, Liang, Hao, Li, Wenzhuo, Wei, Qi, Pan, Mengling, Wen, Xin, Wang, Xingzhi, Zhou, Wei, Yu, Danni, Wang, Hao, Yin, Ni, Chen, Hao, Li, Hansheng, Pan, Ting, Ma, Mingyu, Liu, Gaoqi, Zhou, Wenjia, Su, Zhenhuang, Chen, Qi, Fan, Fengjia, Zheng, Fan, Gao, Xingyu, Ji, Qingqing, Ning, Zhijun
Format Journal Article
LanguageEnglish
Published China Oxford University Press 01.05.2024
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Summary:Enhancing the quality of junctions is crucial for optimizing carrier extraction and suppressing recombination in semiconductor devices. In recent years, metal halide perovskite has emerged as the most promising next-generation material for optoelectronic devices. However, the construction of high-quality perovskite junctions, as well as characterization and understanding of their carrier polarity and density, remains a challenge. In this study, using combined electrical and spectroscopic characterization techniques, we investigate the doping characteristics of perovskite films by remote molecules, which is corroborated by our theoretical simulations indicating Schottky defects consisting of double ions as effective charge dopants. Through a post-treatment process involving a combination of biammonium and monoammonium molecules, we create a surface layer of n-type low-dimensional perovskite. This surface layer forms a heterojunction with the underlying 3D perovskite film, resulting in a favorable doping profile that enhances carrier extraction. The fabricated device exhibits an outstanding open-circuit voltage ( ) up to 1.34 V and achieves a certified efficiency of 19.31% for single-junction wide-bandgap (1.77 eV) perovskite solar cells, together with significantly enhanced operational stability, thanks to the improved separation of carriers. Furthermore, we demonstrate the potential of this wide-bandgap device by achieving a certified efficiency of 27.04% and a of 2.12 V in a perovskite/perovskite tandem solar cell configuration.
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Equally contributed to this work.
ISSN:2095-5138
2053-714X
DOI:10.1093/nsr/nwae055