电解质
溶剂化
化学
离解(化学)
相间
化学工程
离子
聚合物
离子运输机
聚电解质
电化学
枝晶(数学)
无机化学
溶剂化壳
电导率
两性离子
水溶液
金属
单体
纳米技术
电极
离子电导率
化学物理
金属锂
电池容量
导电体
聚合物电解质
极地的
作者
Lu Nie,Xinru Wu,Haotian Qu,Runhua Gao,Xiao Xiao,Zhihong Piao,Gongxun Lu,Wenqiang Fang,Yanfei Zhu,Guangmin Zhou
标识
DOI:10.1073/pnas.2513940123
摘要
Gel polymer electrolytes (GPEs) are promising electrolyte candidates for next-generation Li metal batteries (LMBs). However, the reverse migration of free anions causes uneven distribution of space charges and Li + flux, ultimately accelerating dendrite growth. Additionally, strong ion–solvent interactions lead to high Li + desolvation barriers and sluggish Li + transfer kinetics. To address these issues, we design a zwitterionic GPE, where the synergistic effects of zwitterionic groups promote Li-salt dissociation through ion–dipole interactions and simultaneously restrict anion migration, effectively suppressing space charge-induced dendrite growth. Moreover, the competitive coordination of zwitterions with Li + weakens the Li + -solvent interaction, accelerating interfacial Li + desolvation. Zwitterions in the inner solvation shell of Li + are preferentially reduced before the solvents, forming a conductive N- and S-rich inorganic interphase that enhances cycling stability. As a result, the zwitterionic GPE enables the Li||SPAN cells to deliver a high discharge capacity of 528.3 mAh g −1 at −20 °C, and achieve 79.6% capacity retention after 1,000 cycles. Besides, the Li||SPAN pouch cell, with an active mass loading of 10.5 mg cm −2 , delivers a high discharge capacity of 1.63 Ah and an impressive areal capacity of 16.3 mAh cm −2 . This work highlights the importance of regulating ion transport and ion–solvent chemistry for advanced quasi-solid-state LMBs.
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