Improved fatigue behaviour of perovskite solar cells with an interfacial starch–polyiodide buffer layer

Yu Zhang; Qizhen Song; Guilin Liu; Yihua Chen; Zhenyu Guo; Nengxu Li; Xiuxiu Niu; Zhiwen Qiu; Wentao Zhou; Zijian Huang; Cheng Zhu; Huachao Zai; Sai Ma; Yang Bai; Qi Chen; Wenchao Huang; Qing Zhao; Huanping Zhou

doi:10.1038/s41566-023-01287-w

Improved fatigue behaviour of perovskite solar cells with an interfacial starch–polyiodide buffer layer

Yu Zhang, Qizhen Song, Guilin Liu, Yihua Chen, Zhenyu Guo, Nengxu Li, Xiuxiu Niu, Zhiwen Qiu, Wentao Zhou, Zijian Huang, Cheng Zhu, Huachao Zai, Sai Ma, Yang Bai, Qi Chen, Wenchao Huang, Qing Zhao, Huanping Zhou^*

^*Corresponding author for this work

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

58 Citations (Scopus)

Abstract

Metal halide perovskite solar cells are expected to lead the revolution in photovoltaics. However, due to their soft and ionic lattice, perovskites are sensitive to external stimuli, and the resulting devices suffer from noticeable fatigue under cyclic stressors in real-world applications. Due to the lack of a fundamental understanding of the metastable dynamics of materials degradation, effective means to alleviate device fatigue under cyclic illumination are lacking. Here we introduce a starch–polyiodide supermolecule as a bifunctional buffer layer at the perovskite interface, which can both suppress ion migration and promote defect self-healing. The modified perovskite solar cells exhibit improved stability by retaining 98% of their original power conversion efficiency after operation for 42 diurnal cycles (12/12 h light/dark cycle). The devices also deliver a power conversion efficiency of 24.3% (certified, 23.9%) and an intense electroluminescence with external quantum efficiencies above 12.0%. Our findings shed light on how supramolecular chemistry modulates the metastable dynamics of degradation in perovskites and other materials with soft lattices.

Original language	English
Pages (from-to)	1066-1073
Number of pages	8
Journal	Nature Photonics
Volume	17
Issue number	12
DOIs	https://doi.org/10.1038/s41566-023-01287-w
Publication status	Published - Dec 2023

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Zhang, Y., Song, Q., Liu, G., Chen, Y., Guo, Z., Li, N., Niu, X., Qiu, Z., Zhou, W., Huang, Z., Zhu, C., Zai, H., Ma, S., Bai, Y., Chen, Q., Huang, W., Zhao, Q., & Zhou, H. (2023). Improved fatigue behaviour of perovskite solar cells with an interfacial starch–polyiodide buffer layer. Nature Photonics, 17(12), 1066-1073. https://doi.org/10.1038/s41566-023-01287-w

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title = "Improved fatigue behaviour of perovskite solar cells with an interfacial starch–polyiodide buffer layer",

abstract = "Metal halide perovskite solar cells are expected to lead the revolution in photovoltaics. However, due to their soft and ionic lattice, perovskites are sensitive to external stimuli, and the resulting devices suffer from noticeable fatigue under cyclic stressors in real-world applications. Due to the lack of a fundamental understanding of the metastable dynamics of materials degradation, effective means to alleviate device fatigue under cyclic illumination are lacking. Here we introduce a starch–polyiodide supermolecule as a bifunctional buffer layer at the perovskite interface, which can both suppress ion migration and promote defect self-healing. The modified perovskite solar cells exhibit improved stability by retaining 98% of their original power conversion efficiency after operation for 42 diurnal cycles (12/12 h light/dark cycle). The devices also deliver a power conversion efficiency of 24.3% (certified, 23.9%) and an intense electroluminescence with external quantum efficiencies above 12.0%. Our findings shed light on how supramolecular chemistry modulates the metastable dynamics of degradation in perovskites and other materials with soft lattices.",

author = "Yu Zhang and Qizhen Song and Guilin Liu and Yihua Chen and Zhenyu Guo and Nengxu Li and Xiuxiu Niu and Zhiwen Qiu and Wentao Zhou and Zijian Huang and Cheng Zhu and Huachao Zai and Sai Ma and Yang Bai and Qi Chen and Wenchao Huang and Qing Zhao and Huanping Zhou",

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doi = "10.1038/s41566-023-01287-w",

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AU - Zhang, Yu

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AU - Li, Nengxu

AU - Niu, Xiuxiu

AU - Qiu, Zhiwen

AU - Zhou, Wentao

AU - Huang, Zijian

AU - Zhu, Cheng

AU - Zai, Huachao

AU - Ma, Sai

AU - Bai, Yang

AU - Chen, Qi

AU - Huang, Wenchao

AU - Zhao, Qing

AU - Zhou, Huanping

PY - 2023/12

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N2 - Metal halide perovskite solar cells are expected to lead the revolution in photovoltaics. However, due to their soft and ionic lattice, perovskites are sensitive to external stimuli, and the resulting devices suffer from noticeable fatigue under cyclic stressors in real-world applications. Due to the lack of a fundamental understanding of the metastable dynamics of materials degradation, effective means to alleviate device fatigue under cyclic illumination are lacking. Here we introduce a starch–polyiodide supermolecule as a bifunctional buffer layer at the perovskite interface, which can both suppress ion migration and promote defect self-healing. The modified perovskite solar cells exhibit improved stability by retaining 98% of their original power conversion efficiency after operation for 42 diurnal cycles (12/12 h light/dark cycle). The devices also deliver a power conversion efficiency of 24.3% (certified, 23.9%) and an intense electroluminescence with external quantum efficiencies above 12.0%. Our findings shed light on how supramolecular chemistry modulates the metastable dynamics of degradation in perovskites and other materials with soft lattices.

AB - Metal halide perovskite solar cells are expected to lead the revolution in photovoltaics. However, due to their soft and ionic lattice, perovskites are sensitive to external stimuli, and the resulting devices suffer from noticeable fatigue under cyclic stressors in real-world applications. Due to the lack of a fundamental understanding of the metastable dynamics of materials degradation, effective means to alleviate device fatigue under cyclic illumination are lacking. Here we introduce a starch–polyiodide supermolecule as a bifunctional buffer layer at the perovskite interface, which can both suppress ion migration and promote defect self-healing. The modified perovskite solar cells exhibit improved stability by retaining 98% of their original power conversion efficiency after operation for 42 diurnal cycles (12/12 h light/dark cycle). The devices also deliver a power conversion efficiency of 24.3% (certified, 23.9%) and an intense electroluminescence with external quantum efficiencies above 12.0%. Our findings shed light on how supramolecular chemistry modulates the metastable dynamics of degradation in perovskites and other materials with soft lattices.

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Improved fatigue behaviour of perovskite solar cells with an interfacial starch–polyiodide buffer layer

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