High-performance bismuth-gallium positive electrode for liquid metal battery

Liquid metal battery (LMB) with three-liquid-layer configuration is a promising large-scale energy storage technology due to its facile cell fabrication, low cost and long cycle life. The solid discharge product located at electrolyte/electrode interface seriously impedes the electrode reaction kine...

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Bibliographic Details
Published in:Journal of power sources 2020-10, Vol.472, p.228634, Article 228634
Main Authors: Xie, Hongliang, Zhao, Hailei, Wang, Jie, Chu, Peng, Yang, Zhao, Han, Chongqi, Zhang, Yunchao
Format: Article
Language:English
Subjects:
Bismuth-gallium alloy
Cathode material
Electrochemical performance
Energy storage
Liquid metal battery
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Summary:Liquid metal battery (LMB) with three-liquid-layer configuration is a promising large-scale energy storage technology due to its facile cell fabrication, low cost and long cycle life. The solid discharge product located at electrolyte/electrode interface seriously impedes the electrode reaction kinetics and so causes large polarization voltage, which limits LMB development. In this work, a novel bismuth-gallium alloy (70:30 mol%) positive electrode is designed to address this issue. Bi provides lower operating temperature and high energy density. Ga with low melting point and low density forms Ga-rich Li–Bi-Ga melt (Ga-rich phase), which coexists in the same layer with solid discharge product Li3Bi. The liquid Ga-rich phase offers a fast lithium diffusion path for further lithiation reaction, and so enables an accelerated electrode reaction kinetics, endowing the Li||Bi–Ga system with high discharge voltage (0.67 V at 200 mA cm−2), and high energy efficiency (45% at 1200 mA cm−2), almost twice that of the Li||Bi system. Moreover, the Li||Bi–Ga system demonstrates excellent reversibility and cycle stability with a small fade rate of 0.08% per cycle after 300 charge/discharge cycles. These superior electrochemical performances make the designed Bi–Ga alloy an attractive positive electrode material of LMB for high efficiency large-scale energy storage. [Display omitted] •Electrochemical behavior of Bi–Ga alloy is investigated for liquid metal cells.•The addition of Ga endows the Li||Bi–Ga system with a lower polarization.•The Li||Bi–Ga battery delivers a high discharge voltage platform of 0.67 V.•The Li||Bi–Ga battery demonstrates excellent reversibility and cycle stability.
ISSN:0378-7753
1873-2755
DOI:10.1016/j.jpowsour.2020.228634