材料科学
无定形固体
电解质
自行车
电化学
化学工程
锂(药物)
电化学窗口
离子电导率
电池(电)
电导率
电极
卤化物
阳离子聚合
快离子导体
纳米技术
化学稳定性
离子键合
结构稳定性
无机化学
锂离子电池
降级(电信)
锂电池
离子
容量损失
充电周期
作者
Zecheng Fang,T Liu,Xinglong Jiang,Tenghui Wang,Wen Yin,Yuanguang Xia,Nian Zhang,Biao Deng,Limei Sun,Xiangfeng Liu
摘要
ABSTRACT Halides‐based all‐solid‐state lithium batteries (ASSLBs) attract great attention because of their wide electrochemical window and fine processibility. However, low ionic conductivity of halides and solid‐solid interface incompatibility result in inferior rate capability and poor cycling stability. Herein, we modulate local structure (short‐range‐structure disorder degree, coordination diversity, and so forth) via a synergistic anion–cation strategy to achieve amorphous solid electrolyte 1.6Li 2 O‐TaCl 5 ‐0.3MgF 2 (LTOC‐M) with a high ionic conductivity (11.15 mS cm −1 ) and favorable interfacial compatibility. F incorporation at Cl/O sites strengthens Ta─F bonding and Li–F interactions, enhancing long‐term cycling stability, while Mg incorporation modulates the local cationic environment, increases coordination diversity, and facilitates Li + transport within the amorphous matrix. ASSLBs with LiNi 0.8 Co 0.1 Mn 0.1 O 2 or LiCoO 2 demonstrate superhigh rate capability and long‐term cycling stability (LiNi 0.8 Co 0.1 Mn 0.1 O 2 :92.29%@4000cycles@5C; LiCoO 2 :80.85%@5000cycles@10C). When paired with Li‐rich Li 1.2 Mn 0.54 Ni 0.13 Co 0.13 O 2 , the cell delivers a high initial capacity of 270.38 mAh g −1 with a cycling stability (92.75%@120cycles@0.2C). Moreover, Li‐In| Li 6 PS 5 Cl‐LTOC‐M|LiCoO 2 delivers a high discharge capacity of 128.80 mAh g −1 at −20°C and demonstrates a cycling stability (96.62%@550cycles@0.2C), and the battery functions even at −75°C for over 400 h. The proposed strategy effectively enhances high‐rate performance, long‐term cycling stability and low‐temperature performance of halides‐based ASSLBs, accelerating their practical application.
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