材料科学
离子电导率
电解质
无定形固体
离子键合
离子
法拉第效率
化学工程
快离子导体
卤化物
化学物理
电导率
体积模量
分子动力学
弹性模量
无机化学
协调数
纳米技术
钠
离子液体
模数
铝硅酸钠
作者
Zifei Shi,Yichao Wang,Shouyu Sun,Lingbo Yao,Ning Jiang,Xiaowei Chi,Yu Liu
摘要
ABSTRACT The applicability and long‐term stability of all‐solid‐state Na‐ion batteries (ASSNIBs) depend on maintaining a robust ionic transport interface between electrolytes and electrodes. However, most sodium‐ion solid‐state electrolytes (SSEs) exhibit insufficient ionic conductivity and rigid particle contacts. In this work, a binary amorphous SSE was designed by incorporating high‐polarizability and low‐electronegativity S 2− anions into halide SSEs, featuring mixed S/Cl anionic framework and enhanced flexibility and reorientation dynamics of the anion sublattice, rendering the SSEs both high ionic conductivity (up to 2.12 mS cm −1 at 30°C) and excellent formability (reduction of 63.3% of the Young's modulus to 2.2 GPa and 46% of the hardness to 2.02 GPa). Multi‐scale characterizations and theoretical calculations reveal that the unique S/Cl mixed‐anion framework promotes the structural amorphization and microscopically optimizes the sodium‐ion potential energy landscape by modulating the Na + coordination environment through local polyhedral distortion. Furthermore, the assembled ASSNIBs maintain c.a . 100% coulombic efficiency over long‐term cycling, with a capacity retention of 91% after 270 cycles at 0.2C and 80% for more than 1400 cycles at 1C. Therefore, these findings provide new insights for the development of high‐performance binary SSEs for ASSNIBs and general rules for the design of other ionic SSEs.
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