High-entropy materials for aqueous zinc metal batteries

Xiaomin Han; Ran Zhao; Jingjing Yang; Yahui Wang; Anqi Zhang; Zhifan Hu; Mengge Lv; Chuan Wu; Ying Bai

doi:10.1039/d4ee04442h

High-entropy materials for aqueous zinc metal batteries

Xiaomin Han, Ran Zhao^*, Jingjing Yang, Yahui Wang, Anqi Zhang, Zhifan Hu, Mengge Lv, Chuan Wu^*, Ying Bai^*

^*Corresponding author for this work

Beijing Institute of Technology

Research output: Contribution to journal › Review article › peer-review

6 Citations (Scopus)

Abstract

To overcome the challenges raised by the utilization of intermittent clean energy, rechargeable aqueous zinc metal batteries (AZMBs) stand at the forefront due to their competitive capacity, low cost, and safety metrics. However, the side reactions at the anode, the instability of the cathode and the limited applications of aqueous electrolytes hinder its commercialization. High-entropy materials (HEMs), known for their multi-elemental composition and synergy, have shown great potential to alleviate the failure behaviors in various components, such as the electrochemical instability of electrodes, side reactions and electrolyte incompatibility with the reactive metallic anode. Based on the evaluation of emerging HEM strategies and the failure behavior analysis of AZMBs, this review discloses that the adoption of HEMs could be a universal solution to break the constraints in AZMBs and pave the way toward the development of high-performance AZMBs.

Original language	English
Pages (from-to)	97-129
Number of pages	33
Journal	Energy and Environmental Science
Volume	18
Issue number	1
DOIs	https://doi.org/10.1039/d4ee04442h
Publication status	Published - 5 Nov 2024

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Han, X., Zhao, R., Yang, J., Wang, Y., Zhang, A., Hu, Z., Lv, M., Wu, C., & Bai, Y. (2024). High-entropy materials for aqueous zinc metal batteries. Energy and Environmental Science, 18(1), 97-129. https://doi.org/10.1039/d4ee04442h

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abstract = "To overcome the challenges raised by the utilization of intermittent clean energy, rechargeable aqueous zinc metal batteries (AZMBs) stand at the forefront due to their competitive capacity, low cost, and safety metrics. However, the side reactions at the anode, the instability of the cathode and the limited applications of aqueous electrolytes hinder its commercialization. High-entropy materials (HEMs), known for their multi-elemental composition and synergy, have shown great potential to alleviate the failure behaviors in various components, such as the electrochemical instability of electrodes, side reactions and electrolyte incompatibility with the reactive metallic anode. Based on the evaluation of emerging HEM strategies and the failure behavior analysis of AZMBs, this review discloses that the adoption of HEMs could be a universal solution to break the constraints in AZMBs and pave the way toward the development of high-performance AZMBs.",

author = "Xiaomin Han and Ran Zhao and Jingjing Yang and Yahui Wang and Anqi Zhang and Zhifan Hu and Mengge Lv and Chuan Wu and Ying Bai",

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AU - Han, Xiaomin

AU - Zhao, Ran

AU - Yang, Jingjing

AU - Wang, Yahui

AU - Zhang, Anqi

AU - Hu, Zhifan

AU - Lv, Mengge

AU - Wu, Chuan

AU - Bai, Ying

PY - 2024/11/5

Y1 - 2024/11/5

N2 - To overcome the challenges raised by the utilization of intermittent clean energy, rechargeable aqueous zinc metal batteries (AZMBs) stand at the forefront due to their competitive capacity, low cost, and safety metrics. However, the side reactions at the anode, the instability of the cathode and the limited applications of aqueous electrolytes hinder its commercialization. High-entropy materials (HEMs), known for their multi-elemental composition and synergy, have shown great potential to alleviate the failure behaviors in various components, such as the electrochemical instability of electrodes, side reactions and electrolyte incompatibility with the reactive metallic anode. Based on the evaluation of emerging HEM strategies and the failure behavior analysis of AZMBs, this review discloses that the adoption of HEMs could be a universal solution to break the constraints in AZMBs and pave the way toward the development of high-performance AZMBs.

AB - To overcome the challenges raised by the utilization of intermittent clean energy, rechargeable aqueous zinc metal batteries (AZMBs) stand at the forefront due to their competitive capacity, low cost, and safety metrics. However, the side reactions at the anode, the instability of the cathode and the limited applications of aqueous electrolytes hinder its commercialization. High-entropy materials (HEMs), known for their multi-elemental composition and synergy, have shown great potential to alleviate the failure behaviors in various components, such as the electrochemical instability of electrodes, side reactions and electrolyte incompatibility with the reactive metallic anode. Based on the evaluation of emerging HEM strategies and the failure behavior analysis of AZMBs, this review discloses that the adoption of HEMs could be a universal solution to break the constraints in AZMBs and pave the way toward the development of high-performance AZMBs.

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VL - 18

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JO - Energy and Environmental Science

JF - Energy and Environmental Science

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ER -

High-entropy materials for aqueous zinc metal batteries

Abstract

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