Reasonable Design and Deep Insight of Efficient Integrated Photorechargeable Li-Ion Batteries by Using a Cu/CuO/Cu2S Electrode

Herein, Cu-foam-supported CuO nanowire arrays covered with Cu2S nanosheet substrates (Cu/CuO/Cu2S) are adopted as efficient photoelectrodes for photorechargeable lithium-ion batteries (PR-LIBs). The assembled PR-LIB exhibits remarkable solar energy conversion efficiency alongside superior lithium st...

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Published in:Nano letters 2024-09, Vol.24 (35), p.10827-10833
Main Authors: Wei, Meng, Zhang, Qiuman, Huang, Lisha, Xue, Zhengtao, Gao, Qiongzhi, Cai, Xin, Zhang, Shengsen, Fang, Yueping, Peng, Feng, Yuan, Teng, Yang, Siyuan
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container_end_page 10833
container_issue 35
container_start_page 10827
container_title Nano letters
container_volume 24
creator Wei, Meng
Zhang, Qiuman
Huang, Lisha
Xue, Zhengtao
Gao, Qiongzhi
Cai, Xin
Zhang, Shengsen
Fang, Yueping
Peng, Feng
Yuan, Teng
Yang, Siyuan
description Herein, Cu-foam-supported CuO nanowire arrays covered with Cu2S nanosheet substrates (Cu/CuO/Cu2S) are adopted as efficient photoelectrodes for photorechargeable lithium-ion batteries (PR-LIBs). The assembled PR-LIB exhibits remarkable solar energy conversion efficiency alongside superior lithium storage capabilities. Without an electrical power supply, the photocharged PR-LIB sustained a discharge process for 63.0 h under a constant current density of 0.05 mA cm–2. The corresponding solar-to-electrical energy conversion efficiency is 4.50%, which is an impressive achievement among recently reported contemporary technologies. Mechanism investigation shows that the Cu/CuO/Cu2S photogenerated carriers augment the extraction and insertion of Li+ according to different oxidation and reduction reactions in the charging and discharging reactions. This research delineates a refined model system and proposes innovative directions for developing efficient heterojunction photoelectrodes, significantly propelling the development of PR-LIB technology.
doi_str_mv 10.1021/acs.nanolett.4c02255
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title Reasonable Design and Deep Insight of Efficient Integrated Photorechargeable Li-Ion Batteries by Using a Cu/CuO/Cu2S Electrode
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