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The back electrode is an important factor affecting the performance of perovskite solar cells. In this paper, the effects of back electrode material, structure and thickness on the performance of perovskite solar cells are studied by using COMSOL software. It is found that compared with the work function of the back electrode metal, its resistance has small effect on solar cell performance. Besides the back electrode structures affecting cell performance, there are other factors affecting cell performance. In terms of the back electrodes with honeycomb structure, considering the difficulty in fabricating, the best cost performance occurs when the radius of the circle is approximately equal to the edge spacing. It is predicted that the cell performance will be improved by about 5% in porosity with increasing 10% in the back electrode. The resistance of the back electrode decreases with its thickness increasing. Considering the process and cost, the optimal thickness should be between 100 nm and 150 nm.
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Keywords:
- perovskite solar cell /
- back electrode /
- materials /
- structure /
- thickness
[1] Jeong M, Choi I W, Go E M, Cho Y, Kim M, Lee B, Jeong S, Jo Y, Choi H W, Lee J, Bae J H, Kwak S K, Kim D S, Yang C 2020 Science 369 1615Google Scholar
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Ji C, Liang C J, You T F, He Z Q 2021 Acta Phys. Sin. 70 028402Google Scholar
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Zhu Y, Du C, Wang S, Ma R X, Wang C Y 2020 Chin. J. Eng. 42 16
[7] 彭英才, 傅广生 2014 新概念太阳电池 (北京: 科学出版社) 第38−39页
Peng Y C, Fu G S 2014 New Concept Solar Cell (Beijing: Science Press) pp38−39 (in Chinese)
[8] Wenham S R, Green M A, Watt M E, Corkish R 2007 Applied Photovoltaics (UK: Stylus Pub Llc) pp64−67
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[11] Zhang H, Song K, Zhu L, Meng Q 2020 Carbon 168 372Google Scholar
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[13] Jian W, Xu R P, Li Y Q, Chi L, Chen J D, Zhao X D, Xie Z Z, Lee C S, Zhang W J, Tang J X 2017 Adv. Energy Mater. 7 1700492Google Scholar
[14] Yang W, Yang Z, Shou C, Sheng J, Yan B, Ye J 2020 Sol. Energy 201 84Google Scholar
[15] Behrouznejad F, Tsai C M, Narra S, Diau E, Taghavinia N 2017 ACS Appl. Mater. Interfaces 9 25204Google Scholar
[16] Lin X, Chesman A S R, Raga S R, Scully A D, Jiang L, Tan B, Lu J, Cheng Y B, Bach U 2018 Adv. Funct. Mater. 28 1805098Google Scholar
[17] Jahantigh F, Ghorashi S M B 2019 Nano 14 1950127Google Scholar
[18] Saxena P, Gorji N E 2019 IEEE J. Photovoltaics 9 1693Google Scholar
[19] 王媛, 崔艳, 吴以治 2019 人工晶体学报 48 2075Google Scholar
Wang Y, Cui Y, Wu Y Z 2019 J. Synth. Cryst. 48 2075Google Scholar
[20] 车俐佳, 郭艳群, 邹谭圆, 盛鑫, 赖文志, 蔡传兵 2020 功能材料与器件学报 25 43
Che L J, Guo Y Q, Zou T Y, Sheng X, Lai W Z, Cai C B 2020 J. Funct. Mater. Devices 25 43
[21] 甘永进, 莫沛, 杨瑞兆, 饶俊慧, 李清流, 毕雪光 2021 固体电子学研究与进展 41 53
Gan Y J, Mo P, Yang R Z, Rao J H, Li Q L, Bi X G 2021 Prog. Solid State Electron. 41 53
[22] Hou Q, Dorota B, Jumabekov A N, Wei L, Wang Z, Lin X, Hock N S, Tan B, Bao Q, Chesman A S R, Bing C, Bach U 2018 Nano Energy 50 710Google Scholar
[23] Zhou X, Bao C, Li F M, Gao H, Yu T, Yang J, Zhu W, Zou Z 2015 RSC Adv. 5 58543Google Scholar
[24] Mesquita I, Andrade L, Mendes A 2018 Renewable Sustainable Energy Rev. 82 2471Google Scholar
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[1] Jeong M, Choi I W, Go E M, Cho Y, Kim M, Lee B, Jeong S, Jo Y, Choi H W, Lee J, Bae J H, Kwak S K, Kim D S, Yang C 2020 Science 369 1615Google Scholar
[2] Jiang Q, Zhao Y, Zhang X, Yang X, Chen X, Chu Z, Ye Q, Li X, Yin Z, You J 2019 Nat. Photonics 13 460Google Scholar
[3] 姬超, 梁春军, 由芳田, 何志群 2021 70 028402Google Scholar
Ji C, Liang C J, You T F, He Z Q 2021 Acta Phys. Sin. 70 028402Google Scholar
[4] Zhao Y, Wei J, Li, Y Yan, Zhou W, Yu D, Zhao Q 2016 Nat. Commun. 7 10228Google Scholar
[5] Walter D, Wu Y, Duong T, Peng J, Jiang L, Fong K C, Weber K 2018 Adv. Energy Mater. 8 1701522Google Scholar
[6] 朱彧, 杜晨, 王硕, 马瑞新, 王成彦 2020 工程科学学报 42 16
Zhu Y, Du C, Wang S, Ma R X, Wang C Y 2020 Chin. J. Eng. 42 16
[7] 彭英才, 傅广生 2014 新概念太阳电池 (北京: 科学出版社) 第38−39页
Peng Y C, Fu G S 2014 New Concept Solar Cell (Beijing: Science Press) pp38−39 (in Chinese)
[8] Wenham S R, Green M A, Watt M E, Corkish R 2007 Applied Photovoltaics (UK: Stylus Pub Llc) pp64−67
[9] Lin C Y, Wan C C, Wei T C 2011 Electrochim. Acta 56 1941Google Scholar
[10] Fan Z J, Yi F S, Guo S, Bi Y G 2019 Opt. Eng. 58 017103
[11] Zhang H, Song K, Zhu L, Meng Q 2020 Carbon 168 372Google Scholar
[12] Hu Y, Adhyaksa G W P, DeLuca G, Simonov A N, Duffy N W, Reichmanis E, Bach U, Docampo P, Bein T, Garnett E C, Chesman A S R, Jumabekov A N 2019 AIP Adv. 9 125037Google Scholar
[13] Jian W, Xu R P, Li Y Q, Chi L, Chen J D, Zhao X D, Xie Z Z, Lee C S, Zhang W J, Tang J X 2017 Adv. Energy Mater. 7 1700492Google Scholar
[14] Yang W, Yang Z, Shou C, Sheng J, Yan B, Ye J 2020 Sol. Energy 201 84Google Scholar
[15] Behrouznejad F, Tsai C M, Narra S, Diau E, Taghavinia N 2017 ACS Appl. Mater. Interfaces 9 25204Google Scholar
[16] Lin X, Chesman A S R, Raga S R, Scully A D, Jiang L, Tan B, Lu J, Cheng Y B, Bach U 2018 Adv. Funct. Mater. 28 1805098Google Scholar
[17] Jahantigh F, Ghorashi S M B 2019 Nano 14 1950127Google Scholar
[18] Saxena P, Gorji N E 2019 IEEE J. Photovoltaics 9 1693Google Scholar
[19] 王媛, 崔艳, 吴以治 2019 人工晶体学报 48 2075Google Scholar
Wang Y, Cui Y, Wu Y Z 2019 J. Synth. Cryst. 48 2075Google Scholar
[20] 车俐佳, 郭艳群, 邹谭圆, 盛鑫, 赖文志, 蔡传兵 2020 功能材料与器件学报 25 43
Che L J, Guo Y Q, Zou T Y, Sheng X, Lai W Z, Cai C B 2020 J. Funct. Mater. Devices 25 43
[21] 甘永进, 莫沛, 杨瑞兆, 饶俊慧, 李清流, 毕雪光 2021 固体电子学研究与进展 41 53
Gan Y J, Mo P, Yang R Z, Rao J H, Li Q L, Bi X G 2021 Prog. Solid State Electron. 41 53
[22] Hou Q, Dorota B, Jumabekov A N, Wei L, Wang Z, Lin X, Hock N S, Tan B, Bao Q, Chesman A S R, Bing C, Bach U 2018 Nano Energy 50 710Google Scholar
[23] Zhou X, Bao C, Li F M, Gao H, Yu T, Yang J, Zhu W, Zou Z 2015 RSC Adv. 5 58543Google Scholar
[24] Mesquita I, Andrade L, Mendes A 2018 Renewable Sustainable Energy Rev. 82 2471Google Scholar
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