通过弱溶剂化能力溶剂优化低温下的锂沉积

Optimize Lithium Deposition at Low Temperature by Weakly Solvating Power Solvent.

作者信息

Ma Tao, Ni Youxuan, Wang Qiaoran, Zhang Weijia, Jin Song, Zheng Shibing, Yang Xian, Hou Yunpeng, Tao Zhanliang, Chen Jun

机构信息

Key Laboratory of Advanced Energy Materials Chemistry, Ministry of Education), College of Chemistry, Nankai University, Tianjin, 300071, China.

Haihe Laboratory of Sustainable Chemical Transformations, Tianjin, 300071, China.

出版信息

Angew Chem Int Ed Engl. 2022 Sep 26;61(39):e202207927. doi: 10.1002/anie.202207927. Epub 2022 Aug 23.

DOI:10.1002/anie.202207927

PMID:35924827

Abstract

For lithium (Li) metal batteries, the decrease in operating temperature brings severe safety issues by more disordered Li deposition. Here, we demonstrate that the solvating power of solvent is closely related to the reversibility of the Li deposition/stripping process under low-temperature conditions. The electrolyte with weakly solvating power solvent shows lower desolvation energy, allowing for a uniform Li deposition morphology, as well as a high deposition/stripping efficiency (97.87 % at -40 °C). Based on a weakly solvating electrolyte, we further built a full cell by coupling the Li metal anode with a sulfurized polyacrylonitrile electrode at a low anode-to-cathode capacity ratio for steady cycling at -40 °C. Our results clarified the relationship between solvating power of solvent and Li deposition behavior at low temperatures.

摘要

对于锂金属电池，工作温度的降低会因锂沉积更加无序而带来严重的安全问题。在此，我们证明了溶剂的溶剂化能力与低温条件下锂沉积/剥离过程的可逆性密切相关。具有弱溶剂化能力溶剂的电解质显示出较低的去溶剂化能，可实现均匀的锂沉积形态以及较高的沉积/剥离效率（在-40°C时为97.87%）。基于弱溶剂化电解质，我们进一步通过以低阳极与阴极容量比将锂金属阳极与硫化聚丙烯腈电极耦合，构建了一个全电池，以在-40°C下实现稳定循环。我们的结果阐明了溶剂的溶剂化能力与低温下锂沉积行为之间的关系。

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通过弱溶剂化能力溶剂优化低温下的锂沉积

Optimize Lithium Deposition at Low Temperature by Weakly Solvating Power Solvent.

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