电解质
材料科学
电池(电)
金属锂
锂(药物)
稀释剂
耐久性
化学工程
溶剂化
储能
纳米技术
有机自由基电池
锂电池
金属
电极
无机化学
溶剂
锂离子电池
离子液体
两亲性
集电器
作者
Hyeonmin Jo,Uijun Lee,Jin Hwan Kwak,Jungjin Park,Jiyoung Yun,Seonju Kim,J.-H. Lee,Hee Seung Ryu,Sunjin Park,Cheolwoo Jo,Byunghoon Kim,Hee‐Dae Lim
标识
DOI:10.1002/adma.202522875
摘要
Advancing liquid electrolyte design is crucial for overcoming the performance limitations of current battery technologies and enabling next-generation energy storage systems. Among recent developments, localized high-concentration electrolytes (LHCEs) have demonstrated remarkable cycling stability. However, their reliance on fluorinated diluents, which are highly reactive with lithium metal, inevitably leads to severe spontaneous corrosion. This study introduces a fluorine-free, corrosion-resistant diluent (CRD) strategy, employing benzene as the CRD in combination with amphiphilic butyl methyl ether as the primary solvent. This electrolyte design simultaneously extends both cycle and calendar life by promoting an anion-dominated solvation structure, while the diluent effectively suppresses lithium metal corrosion. As a result, the CRD-based electrolyte exhibits outstanding durability and stability compared to conventional LHCEs. Moreover, the fluorine-free and cost-effective electrolyte-diluent system offers strong advantages for practical applications. Overall, this study demonstrates the potential of the CRD strategy to achieve stable electrode-electrolyte interfaces and provides broader insights for diverse battery chemistries.
科研通智能强力驱动
Strongly Powered by AbleSci AI