可调带隙硫硒化锑薄膜及太阳电池的研究进展

Yu Cao; Ying Wu; Jing Zhou; Jian Ni; Jian Jun Zhang; Jia Hua Tao; Jun Hao Chu

doi:10.11972/j.issn.1001-9014.2023.03.005

可调带隙硫硒化锑薄膜及太阳电池的研究进展

Translated title of the contribution: Research progress on tunable band gap antimony sulfoselenide thin films and solar cells

Yu Cao, Ying Wu, Jing Zhou^*, Jian Ni, Jian Jun Zhang, Jia Hua Tao^*, Jun Hao Chu

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

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 Sb（₂ S，Se）₃ thin film is systematically introduced. Secondly，the selection of each functional layer and the gradient bandgap structure of Sb（₂ S，Se）₃ solar cells are analyzed. Finally，the large-scale preparation of Sb（₂ S，Se）₃ solar 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 Sb（₂ S，Se）₃ solar cells.

Translated title of the contribution	Research progress on tunable band gap antimony sulfoselenide thin films and solar cells
Original language	Chinese (Traditional)
Pages (from-to)	311-326
Number of pages	16
Journal	Hongwai Yu Haomibo Xuebao/Journal of Infrared and Millimeter Waves
Volume	42
Issue number	3
DOIs	https://doi.org/10.11972/j.issn.1001-9014.2023.03.005
State	Published - Jun 2023
Externally published	Yes

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title = "可调带隙硫硒化锑薄膜及太阳电池的研究进展",

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 Sb（2 S，Se）3 thin film is systematically introduced. Secondly，the selection of each functional layer and the gradient bandgap structure of Sb（2 S，Se）3 solar cells are analyzed. Finally，the large-scale preparation of Sb（2 S，Se）3 solar 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 Sb（2 S，Se）3 solar cells.",

keywords = "Sb (S,Se) solar cell, carrier transport layer, gradient bandgap, preparation methods",

author = "Yu Cao and Ying Wu and Jing Zhou and Jian Ni and Zhang, \{Jian Jun\} and Tao, \{Jia Hua\} and Chu, \{Jun Hao\}",

year = "2023",

month = jun,

doi = "10.11972/j.issn.1001-9014.2023.03.005",

language = "繁体中文",

volume = "42",

pages = "311--326",

journal = "Hongwai Yu Haomibo Xuebao/Journal of Infrared and Millimeter Waves",

issn = "1001-9014",

publisher = "Chinese Optical Society",

number = "3",

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T1 - 可调带隙硫硒化锑薄膜及太阳电池的研究进展

AU - Cao, Yu

AU - Wu, Ying

AU - Zhou, Jing

AU - Ni, Jian

AU - Zhang, Jian Jun

AU - Tao, Jia Hua

AU - Chu, Jun Hao

PY - 2023/6

Y1 - 2023/6

N2 - 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 Sb（2 S，Se）3 thin film is systematically introduced. Secondly，the selection of each functional layer and the gradient bandgap structure of Sb（2 S，Se）3 solar cells are analyzed. Finally，the large-scale preparation of Sb（2 S，Se）3 solar 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 Sb（2 S，Se）3 solar cells.

AB - 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 Sb（2 S，Se）3 thin film is systematically introduced. Secondly，the selection of each functional layer and the gradient bandgap structure of Sb（2 S，Se）3 solar cells are analyzed. Finally，the large-scale preparation of Sb（2 S，Se）3 solar 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 Sb（2 S，Se）3 solar cells.

KW - Sb (S,Se) solar cell

KW - carrier transport layer

KW - gradient bandgap

KW - preparation methods

UR - https://www.scopus.com/pages/publications/85161522672

U2 - 10.11972/j.issn.1001-9014.2023.03.005

DO - 10.11972/j.issn.1001-9014.2023.03.005

M3 - 文章

AN - SCOPUS:85161522672

SN - 1001-9014

VL - 42

SP - 311

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JO - Hongwai Yu Haomibo Xuebao/Journal of Infrared and Millimeter Waves

JF - Hongwai Yu Haomibo Xuebao/Journal of Infrared and Millimeter Waves

IS - 3

ER -

可调带隙硫硒化锑薄膜及太阳电池的研究进展

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