材料科学
离子电导率
电解质
纤维素
化学工程
锂(药物)
离子液体
表面改性
纳米技术
聚合物
电池(电)
相(物质)
粘附
电导率
离子键合
陶瓷
金属锂
导电体
锂离子电池
纤维
吸附
电极
离子
工作(物理)
作者
Chengshuai Chang,Xian Wu,Mengtian Zhang,Haotian Qu,Xiao Xiao,Zhoujie Lao,Guangmin Zhou
摘要
ABSTRACT Solid‐state electrolytes (SSEs) offer a promising pathway for replacing flammable liquid electrolytes in lithium metal batteries. However, their widespread application remains limited by low ionic conductivity, interfacial incompatibility, and high production costs. Here we introduce a cellulose‐based SSE featuring sulfonyl‐functionalized polymer chains that simultaneously enhance ionic transport and interfacial adhesion. The rich microdomain gradient‐concentration sulfonated cellulose (RMGC‐SC) achieves optimal ionic conductivity (1.11 × 10 −3 S cm −1 ) and intimate interface contact, and supports 1000 h of uninterrupted plating/stripping in Li||Li symmetric cells at 0.2 mA cm −2 (0.2 mAh cm −2 ). Moreover, Li||LiFePO 4 coin cells deliver outstanding cycling performance with a minimal capacity fade of only 0.023% per cycle, and a 5 × 5 cm 2 pouch cell with an areal loading of 11.2 mg cm −2 still retains 94.9% of its initial capacity, highlighting the electrolyte's practical robustness. Furthermore, a non‐solvent‐induced phase separation strategy enables efficient recovery and reuse of the cellulose matrix and lithium salt, establishing a closed‐loop recycling approach that reduces costs and environmental impact. This work demonstrates the potential of polymer molecular functionalization in precisely tuning SSE properties, offering a sustainable and scalable pathway toward high‐performance solid‐state battery technologies.
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