Interpenetrating interfaces for efficient perovskite solar cells with high operational stability and mechanical robustness

Qingshun Dong; Chao Zhu; Min Chen; Chen Jiang; Jingya Guo; Yulin Feng; Zhenghong Dai; Srinivas K. Yadavalli; Mingyu Hu; Xun Cao; Yuqian Li; Yizhong Huang; Zheng Liu; Yantao Shi; Liduo Wang; Nitin P. Padture; Yuanyuan Zhou

doi:10.1038/s41467-021-21292-3

Interpenetrating interfaces for efficient perovskite solar cells with high operational stability and mechanical robustness

Qingshun Dong, Chao Zhu, Min Chen, Chen Jiang, Jingya Guo, Yulin Feng, Zhenghong Dai, Srinivas K. Yadavalli, Mingyu Hu, Xun Cao, Yuqian Li, Yizhong Huang, Zheng Liu, Yantao Shi^*, Liduo Wang, Nitin P. Padture^*, Yuanyuan Zhou^*

^*Corresponding author for this work

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

236 Citations (Scopus)

Abstract

The perovskite solar cell has emerged rapidly in the field of photovoltaics as it combines the merits of low cost, high efficiency, and excellent mechanical flexibility for versatile applications. However, there are significant concerns regarding its operational stability and mechanical robustness. Most of the previously reported approaches to address these concerns entail separate engineering of perovskite and charge-transporting layers. Herein we present a holistic design of perovskite and charge-transporting layers by synthesizing an interpenetrating perovskite/electron-transporting-layer interface. This interface is reaction-formed between a tin dioxide layer containing excess organic halide and a perovskite layer containing excess lead halide. Perovskite solar cells with such interfaces deliver efficiencies up to 22.2% and 20.1% for rigid and flexible versions, respectively. Long-term (1000 h) operational stability is demonstrated and the flexible devices show high endurance against mechanical-bending (2500 cycles) fatigue. Mechanistic insights into the relationship between the interpenetrating interface structure and performance enhancement are provided based on comprehensive, advanced, microscopic characterizations. This study highlights interface integrity as an important factor for designing efficient, operationally-stable, and mechanically-robust solar cells.

Original language	English
Article number	973
Journal	Nature Communications
Volume	12
Issue number	1
DOIs	https://doi.org/10.1038/s41467-021-21292-3
Publication status	Published - Dec 1 2021
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2021, The Author(s).

ASJC Scopus Subject Areas

General Chemistry
General Biochemistry,Genetics and Molecular Biology
General Physics and Astronomy

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Dong, Q., Zhu, C., Chen, M., Jiang, C., Guo, J., Feng, Y., Dai, Z., Yadavalli, S. K., Hu, M., Cao, X., Li, Y., Huang, Y., Liu, Z., Shi, Y., Wang, L., Padture, N. P., & Zhou, Y. (2021). Interpenetrating interfaces for efficient perovskite solar cells with high operational stability and mechanical robustness. Nature Communications, 12(1), Article 973. https://doi.org/10.1038/s41467-021-21292-3

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title = "Interpenetrating interfaces for efficient perovskite solar cells with high operational stability and mechanical robustness",

abstract = "The perovskite solar cell has emerged rapidly in the field of photovoltaics as it combines the merits of low cost, high efficiency, and excellent mechanical flexibility for versatile applications. However, there are significant concerns regarding its operational stability and mechanical robustness. Most of the previously reported approaches to address these concerns entail separate engineering of perovskite and charge-transporting layers. Herein we present a holistic design of perovskite and charge-transporting layers by synthesizing an interpenetrating perovskite/electron-transporting-layer interface. This interface is reaction-formed between a tin dioxide layer containing excess organic halide and a perovskite layer containing excess lead halide. Perovskite solar cells with such interfaces deliver efficiencies up to 22.2% and 20.1% for rigid and flexible versions, respectively. Long-term (1000 h) operational stability is demonstrated and the flexible devices show high endurance against mechanical-bending (2500 cycles) fatigue. Mechanistic insights into the relationship between the interpenetrating interface structure and performance enhancement are provided based on comprehensive, advanced, microscopic characterizations. This study highlights interface integrity as an important factor for designing efficient, operationally-stable, and mechanically-robust solar cells.",

author = "Qingshun Dong and Chao Zhu and Min Chen and Chen Jiang and Jingya Guo and Yulin Feng and Zhenghong Dai and Yadavalli, {Srinivas K.} and Mingyu Hu and Xun Cao and Yuqian Li and Yizhong Huang and Zheng Liu and Yantao Shi and Liduo Wang and Padture, {Nitin P.} and Yuanyuan Zhou",

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doi = "10.1038/s41467-021-21292-3",

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Dong, Q, Zhu, C, Chen, M, Jiang, C, Guo, J, Feng, Y, Dai, Z, Yadavalli, SK, Hu, M, Cao, X, Li, Y, Huang, Y , Liu, Z, Shi, Y, Wang, L, Padture, NP & Zhou, Y 2021, 'Interpenetrating interfaces for efficient perovskite solar cells with high operational stability and mechanical robustness', Nature Communications, vol. 12, no. 1, 973. https://doi.org/10.1038/s41467-021-21292-3

TY - JOUR

T1 - Interpenetrating interfaces for efficient perovskite solar cells with high operational stability and mechanical robustness

AU - Dong, Qingshun

AU - Zhu, Chao

AU - Chen, Min

AU - Jiang, Chen

AU - Guo, Jingya

AU - Feng, Yulin

AU - Dai, Zhenghong

AU - Yadavalli, Srinivas K.

AU - Hu, Mingyu

AU - Cao, Xun

AU - Li, Yuqian

AU - Huang, Yizhong

AU - Liu, Zheng

AU - Shi, Yantao

AU - Wang, Liduo

AU - Padture, Nitin P.

AU - Zhou, Yuanyuan

PY - 2021/12/1

Y1 - 2021/12/1

N2 - The perovskite solar cell has emerged rapidly in the field of photovoltaics as it combines the merits of low cost, high efficiency, and excellent mechanical flexibility for versatile applications. However, there are significant concerns regarding its operational stability and mechanical robustness. Most of the previously reported approaches to address these concerns entail separate engineering of perovskite and charge-transporting layers. Herein we present a holistic design of perovskite and charge-transporting layers by synthesizing an interpenetrating perovskite/electron-transporting-layer interface. This interface is reaction-formed between a tin dioxide layer containing excess organic halide and a perovskite layer containing excess lead halide. Perovskite solar cells with such interfaces deliver efficiencies up to 22.2% and 20.1% for rigid and flexible versions, respectively. Long-term (1000 h) operational stability is demonstrated and the flexible devices show high endurance against mechanical-bending (2500 cycles) fatigue. Mechanistic insights into the relationship between the interpenetrating interface structure and performance enhancement are provided based on comprehensive, advanced, microscopic characterizations. This study highlights interface integrity as an important factor for designing efficient, operationally-stable, and mechanically-robust solar cells.

AB - The perovskite solar cell has emerged rapidly in the field of photovoltaics as it combines the merits of low cost, high efficiency, and excellent mechanical flexibility for versatile applications. However, there are significant concerns regarding its operational stability and mechanical robustness. Most of the previously reported approaches to address these concerns entail separate engineering of perovskite and charge-transporting layers. Herein we present a holistic design of perovskite and charge-transporting layers by synthesizing an interpenetrating perovskite/electron-transporting-layer interface. This interface is reaction-formed between a tin dioxide layer containing excess organic halide and a perovskite layer containing excess lead halide. Perovskite solar cells with such interfaces deliver efficiencies up to 22.2% and 20.1% for rigid and flexible versions, respectively. Long-term (1000 h) operational stability is demonstrated and the flexible devices show high endurance against mechanical-bending (2500 cycles) fatigue. Mechanistic insights into the relationship between the interpenetrating interface structure and performance enhancement are provided based on comprehensive, advanced, microscopic characterizations. This study highlights interface integrity as an important factor for designing efficient, operationally-stable, and mechanically-robust solar cells.

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Interpenetrating interfaces for efficient perovskite solar cells with high operational stability and mechanical robustness

Abstract

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