Gram-Scale Synthesis of Nanosized Li3HoBr6 Solid Electrolyte for All-Solid-State Li-Se Battery

Rare earth (RE) based halide solid electrolytes (HEs) are recently considered as research hotspots in the field of all-solid-state batteries (ASSBs). The RE-based HEs possess high ionic conductivity, credible deformability, and good stability, which can bring excellent electrochemical performances for ASSBs. However, the conventional synthetic methods of RE HEs are a mechanochemical process and co-melting strategy, both approaches require expensive raw materials and sophisticated equipment. Therefore, a lot of research work is required to promote the preparation methods for these promising SSEs in ASSBs. Thus, a vacuum evaporation-assisted synthesis method is developed for the massive synthesis of HEs. The as-prepared Li3HoBr6 (LHB) has a high lithium-ion conductivity close to the mS cm(-1) level and the LHB-based Li-Se ASSBs can be assembled by cold pressing. Theoretical calculations have revealed that the Li migrations are highly preferred in Li3HoBr6 owing to the low energy cost and high tolerance of stable structure. The tetrahedral and octahedral pathways are responsible for Li migrations in short and long ranges, respectively. The results show that the LHB-based Li-Se battery has good stability and rate performance, indicating that LHB has potential application in the field of ASSBs.

Automated summary

Rare earth-based halide solid electrolytes have high ionic conductivity and good stability, but traditional synthesis methods are costly. A vacuum evaporation-assisted synthesis method was developed for mass production of Li3HoBr6, showing high lithium-ion conductivity and potential application in all-solid-state batteries.