Effect of Pb 6s2 Lone Pair on the Potential Flattening of Fluoride-Ion Conduction in Perovskite-Type Fluoride

Materials containing ns(2) lone pairs exhibit superior fluoride-ion conductivity, acting as promising candidates for solid electrolytes in all-solid-state fluoride-ion batteries. However, the effect of lone pairs on fluoride-ion conduction remains unclear, especially for 6s(2) in Pb2+. This study investigated the relationships between the ionic conductivity, crystal structure, and electronic structure of CsPb0.9K0.1F2.9. Cubic CsPb0.9K0.1F2.9 exhibited a low activation energy of 7.9 kJ mol(-1), resulting in high conductivity at 223 K (1.0 x 10(-3) S cm(-1), bulk conductivity). F-19 nuclear magnetic resonance spectroscopy confirmed facile local migration of the fluoride ions with a low activation barrier of 3.8 kJ mol(-1). Theoretical calculations revealed that the fluoride ions migrated with a low migration energy via an exchange reaction between the Pb 6s lone pairs and fluoride ions. The localised lone pair in the PbF5 polyhedron stabilised the saddle-point structure and mitigated the migration barrier. These findings are beneficial for material design, providing superionic conductivity with a low migration barrier for fluoride ions as well as other anions, such as oxide and chloride.