溶剂化
化学
电解质
溶解度
锂(药物)
盐(化学)
无机化学
金属锂
两亲性
离子
相容性(地球化学)
化学工程
化学物理
碳酸盐
金属
电化学
碳酸丙烯酯
水溶液
计算化学
碳酸锂
分子动力学
熵(时间箭头)
锂电池
溶剂化壳
合理设计
COSMO-RS公司
组态熵
作者
Yingchun Xia,Da Zhu,Wenhui Hou,Pan Zhou,Yu Ou,Haiyu Zhou,Xuan Song,Weili Zhang,Shuaishuai Yan,Yang Lu,Xiao Ma,Yunxiong Zeng,Hong Xu,Kai Liu
摘要
High-entropy electrolytes (HEEs), typically formed by mixing over four types of salts or solvents, have attracted considerable attention due to their diverse solvation microenvironments that improve the cyclability of high-energy lithium metal batteries (LMBs). However, knowledge of salt screening is limited beyond merely increasing the number of salts in electrolyte formulations to increase the solvation configurations. Here, we present a new design principle for constructing an HEE (LTFA-LDFN) by selecting lithium salts containing amphiphilic anions with asymmetric Li + -chelating capabilities (i.e., trifluoroacetate) together with anions featuring multiple Li + coordination sites (i.e., difluorophosphate and nitrate). The amphiphilic trifluoroacetate, containing both a high donor number and a noncoordinating moiety, competitively coordinates with Li + from poorly soluble lithium difluorophosphate and lithium nitrate, disrupting their inherent three-dimensional cation–anion network and enhancing solubility in carbonate solvents. Molecular dynamics calculations further reveal that LTFA-LDFN supports 64 distinct Li + solvation configurations within the top 80% of all configurations, with 71.2% being anion-dominated─unlike the fully solvent-coordinated configurations in conventional carbonate electrolytes. As quantified using the Boltzmann equation, LTFA-LDFN reached a solvation configurational entropy of up to 6.5 × 10 –23 J K –1 . Such high-entropy solvation characteristics enhance the compatibility of Li||NCM811 cells with carbonate electrolytes, achieving stable cycling for over 1000 cycles with 80.2% capacity retention at room temperature under 1 C and more than 300 cycles with over 80% retention at 60 °C under 2 C. Our findings underscore the significant potential of delicate anion engineering to achieve high-entropy-like configuration diversity, paving a new way for advancements in LMBs and beyond.
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