Abstract

Abstract One key research point of solid‐state electrolytes (SSEs) is ionic conductivity. To date, their ionic conductivity is relatively low to meet the requirements of practical applications; thus, more investigations on the migration mechanisms are needed. Here, we constructed scandium‐based halide SSEs (Li 3‐ x Sc 1‐ x (Zr/Hf) x Cl 6 , x = 0 ~ 0.5). The highest ionic conductivities (1.61 and 1.33 mS/cm) and the lowest activation energies (0.326 and 0.323 eV) are shown in Li 2.6 Sc 0.6 Zr 0.4 Cl 6 (LSZC~0.4) and Li 2.6 Sc 0.6 Hf 0.4 Cl 6 (LSHC~0.4), respectively. Their electrochemical windows in the cells of Li/Li 7 P 3 S 11 /LSZC~0.4/LSZC~0.4‐C and Li/Li 7 P 3 S 11 /LSHC~0.4/LSHC~0.4‐C are 1.3 ~ 4.2 V and 1.6 ~ 4.1 V versus Li + /Li, respectively. The crystal structures and the Li + chemical environments were investigated by X‐ray diffraction and 7 Li solid‐state magic angle spinning nuclear magnetic resonance, indicating weaker bond strengths of LiCl to facilitate the transportation of Li + . The potential reason explaining the increased ionic conductivity was determined based on the bond valence site energy theory. image