Research progress on tunable band gap antimony sulfoselenide thin films and solar cells

doi:10.11972/j.issn.1001-9014.2023.03.005

Home > Archive>Volume 42, Issue 3, 2023 >311-326. DOI:10.11972/j.issn.1001-9014.2023.03.005

Research progress on tunable band gap antimony sulfoselenide thin films and solar cells
DOI:
                        10.11972/j.issn.1001-9014.2023.03.005
                    
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Affiliation:1.Key Laboratory of Modern Power System Simulation and Control & Renewable Energy Technology， Ministry of Education， School of Electrical Engineering， School of Chemical Engineering， Northeast Electric Power University， Jilin 132012， China;2.College of Electronic Information and Optical Engineering， Nankai University， Tianjin 300350， China;3.Nanophotonics and Advanced Instrument Engineering Research Center， Ministry of Education， Key Laboratory of Polar Materials and Devices， Ministry of Education， East China Normal University， Shanghai 200241， China;4.National Laboratory for Infrared Physics， Shanghai Institute of Technical Physics， Chinese Academy of Sciences， Shanghai 200083， China;5.Institute of Optoelectronics， Shanghai Frontier Base of Intelligent Optoelectronics and Perception， Fudan University， Shanghai 200433， China
Clc Number:TM914.4
Fund Project:Supported by the National Natural Science Foundation of China （52172185， 51772049）； the Science and Technology Project of the Education Department of Jilin Province （JJKH20220110KJ）； the Natural Science Foundation of Jilin Province （YDZJ202201ZYTS390）， the National Engineering Laboratory for Digital Construction and Evaluation of Urban Rail transit （2021HJ05）， and Natural Science Foundation of Shanghai （20ZR1417400）

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Abstract:

Antimony selenosulfide （Sb₂（S，Se）₃） thin film solar cells have become a research hot spot in recent years due to their simple preparation method， abundant raw materials， low toxicity， stable performance， etc. Their power conversion efficiencies have exceeded 10%， showing the potential for industrialization. The research focus on Sb₂（S，Se）₃ solar cells is to improve the quality of the absorption layer and optimize the device structure. Firstly， the mainstream growth process of Sb₂（S，Se）₃ thin film is systematically introduced. Secondly， the selection of each functional layer and the gradient bandgap structure of Sb₂（S，Se）₃ solar cells are analyzed. Finally， the large-scale preparation of Sb₂（S，Se）₃solar cells and their application potential in antimony-based multi-junction solar cells are further prospected to provide a feasible reference for promoting the industrialization of Sb₂（S，Se）₃ solar cells.

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CAO Yu, WU Ying, ZHOU Jing, NI Jian, ZHANG Jian-Jun, TAO Jia-Hua, CHU Jun-Hao. Research progress on tunable band gap antimony sulfoselenide thin films and solar cells[J]. Journal of Infrared and Millimeter Waves,2023,42(3):311~326

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Received:November 07,2022
Revised:March 31,2023
Adopted:December 06,2022
Online: March 30,2023
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