Suppressing lithium dendrites within inorganic solid-state electrolytes

The Li metal anode possesses the high specific capacity and the minimum reduction potential known as the renaissance of high-energy-density battery. However, the security problems brought by uncontrolled Li dendrites have hindered its development. Integrating the Li metal anode with non-flammable so...

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Published in:Cell reports physical science 2022-01, Vol.3 (1), p.100706, Article 100706
Main Authors: Lv, Qiang, Jiang, Yunpeng, Wang, Bo, Chen, Yujia, Jin, Fan, Wu, Bochen, Ren, Huaizheng, Zhang, Nan, Xu, Ruoyu, Li, Yaohua, Zhang, Tianren, Zhou, Yu, Wang, Dianlong, Liu, Huakun, Dou, Shixue
Format: Article
Language:English
Subjects:
Advanced characterization techniques and theoretical calculations
Causes of Li dendrites within inorganic SSEs
Inorganic solid-state electrolytes
Suppressing Li dendrites
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Summary:The Li metal anode possesses the high specific capacity and the minimum reduction potential known as the renaissance of high-energy-density battery. However, the security problems brought by uncontrolled Li dendrites have hindered its development. Integrating the Li metal anode with non-flammable solid-state electrolytes (SSEs) provides a promising approach to solve the problem of Li dendrites and achieve safe Li metal batteries. However, recent studies indicate that Li dendrites still occur in the interior of inorganic SSEs, although the high mechanical strength of inorganic SSEs can resist dendrite growth in theory. In this review, the main causes of Li dendrites within inorganic SSEs are summarized. Combined with advanced characterization techniques and theoretical calculations, theoretical models of Li dendrite growth within SSEs are clarified. Furthermore, various strategies for suppressing Li dendrites are comprehensively summarized. Finally, the research prospects of dendrite-free all-solid-state Li metal batteries are evaluated. [Display omitted] Lv et al. provide a review of the causes of lithium dendrite growth within inorganic SSEs. Combined with advanced characterization techniques and theoretical calculations, mechanistic models and suppression method of lithium dendrite growth are clarified. Furthermore, the research prospects of dendrite-free solid-state lithium metal batteries are evaluated.
ISSN:2666-3864
2666-3864
DOI:10.1016/j.xcrp.2021.100706