电解质
离子电导率
无定形固体
电化学
离子键合
材料科学
电导率
锂(药物)
阴极
快离子导体
无机化学
卤化物
亚稳态
化学工程
电化学窗口
锂电池
相(物质)
化学
化学稳定性
储能
化学物理
无定形碳
离子
物理化学
作者
Adil Saleem,Junquan Ou,Leon L. Shaw,Bushra Jabar,Mehwish Khalid Butt
标识
DOI:10.1016/j.est.2025.120331
摘要
Inorganic solid electrolyte (SE)-based all-solid-state batteries have attracted huge attention as a potential next-generation energy storage technology. Among them, halide compounds are especially interesting candidates for SEs owing to their remarkable ionic conductivity (≥ 11 mS cm −1 ) at room temperature, great oxidation stability and deformability. This work presents a sophisticated computational approach to examine the phase stability, ionic conductivity, electrochemical behavior and compatibility with typical cathode materials, of lithium oxyhalide (1.6Li 2 O-TaCl 5 ; named as LOTC) which has exhibited an excellent ionic conductivity (∼13.8 mS cm −1 ) at room temperature. Different from the prevailing mechanisms based on concerted Li-ion motions and rotations of anions, vibrations of Cl − anions and dynamic Li Cl interactions via Li Cl networks are key to the fast movement of Li-ions in amorphous LOTC. The results also indicate that the LOTC structure is thermodynamically metastable and the interface of LOTC with LiFePO 4 and LiMn 1.5 Ni 0.5 O 4 cathodes exhibits significantly improved chemical stability. The results provide fresh insights for creating effective materials for solid-state technologies and demonstrate the potential of LOTC for use in high-performance energy storage systems. • Amorphous lithium oxyhalide offers high ionic conductivity (13.8 mS cm −1 ). • The amorphous structure leads to higher lithium-ion conduction. • The designed lithium oxyhalide is thermodynamically metastable. • However, it is electrochemically stable with LiFePO 4 and LiMn 1.5 Ni 0.5 O 4 .
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