电解质
电池(电)
材料科学
阳极
溶剂
锂(药物)
钝化
金属锂
化学工程
锂硫电池
电极
无机化学
纳米技术
化学
有机化学
医学
物理化学
内分泌学
功率(物理)
物理
量子力学
图层(电子)
工程类
作者
David J. Kautz,Xia Cao,Peiyuan Gao,Shuo Feng,Qian Zhao,Saurabh Parab,Yaobin Xu,Joseph P. Quinn,Muhammad Mominur Rahman,Sha Tan,Xin Zhang,Sanaz Ketabi,Aqsa Nazir,Junxia Wang,Fang Dai,Shen Wang,Dongping Lu,Enyuan Hu,Ying Shirley Meng,Chongmin Wang
标识
DOI:10.1002/adma.202503365
摘要
New electrolytes are critical for high-energy lithium (Li)-sulfur (S) batteries (LSBs) to ensure their stability against Li metal anode and polysulfides (PSs) shuttling which hinder the large-scale application of LSBs. In this study, the design principle of moderately solvating electrolytes (MSEs) for LSBs is demonstrated by using a multiple-solvent system comprising of a highly solvating solvent, a weakly solvating solvent, and a non-solvating solvent to create a well-balanced electrolyte system. This resulting electrolyte significantly improves the cycle life of LSBs, achieving 300 cycles, which is twice as long as that of similar cells with the conventional electrolyte and it also ensures stable calendar life for at least seven months. The optimal MSE forms robust passivation layers enhancing the structural integrity of both S and Li metal electrodes after cycling. These virtues effectively hinder parasitic side reactions and self-discharge behavior of LSBs. This electrolyte design principle is versatile and can be applied to other battery chemistries, providing a potential path toward the development of a more efficient and stable battery system. By addressing key challenges such as the instability of electrodes and shuttling of polysulfides, this electrolyte approach offers promising solutions for advancing LSB technology.
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