Solid-State Electrolyte Design for Lithium Dendrite Suppression

All-solid-state Li metal batteries have attracted extensive attention due to their high safety and high energy density. However, Li dendrite growth in solid-state electrolytes (SSEs) still hinders their application. Current efforts mainly aim to reduce the interfacial resistance, neglecting the intrinsic dendrite-suppression capability of SSEs. Herein, the mechanism for the formation of Li dendrites is investigated, and Li-dendrite-free SSE criteria are reported. To achieve a high dendrite-suppression capability, SSEs should be thermodynamically stable with a high interface energy against Li, and they should have a low electronic conductivity and a high ionic conductivity. A cold-pressed Li₃N–LiF composite is used to validate the Li-dendrite-free design criteria, where the highly ionic conductive Li₃N reduces the Li plating/stripping overpotential, and LiF with high interface energy suppresses dendrites by enhancing the nucleation energy and suppressing the Li penetration into the SSEs. The Li₃N–LiF layer coating on Li₃PS₄ SSE achieves a record-high critical current of >6 mA cm⁻² even at a high capacity of 6.0 mAh cm⁻². The Coulombic efficiency also reaches a record 99% in 150 cycles. The Li₃N–LiF/Li₃PS₄ SSE enables LiCoO₂ cathodes to achieve 101.6 mAh g⁻¹ for 50 cycles. The design principle opens a new opportunity to develop high-energy all-solid-state Li metal batteries.