Elucidating Interfacial Phenomena between Solid-State Electrolytes and the Sulfur-Cathode of Lithium-Sulfur Batteries

Sulfide solid-state electrolytes are promising materials to be used in Li-S batteries because they have the potential to mitigate some of the challenges currently faced by this technology such as the dissolution of polysulfide species and the flammability of conventional organic-based electrolytes. Nevertheless, the electrode/electrolyte interfaces are not well-understood yet. In this study, we use density functional theory and ab initio molecular dynamics simulations to investigate the formation of the cathode-electrolyte interface at two limiting states of charge: S-8 and Li2S. beta-Li3PS4 and two lithium halide-doped sulfides (Li6PS5Cl and Li(7)P(2)S8I) were selected because of their Li-ion superionic conductivity and compatibility with sulfur electrodes. The work of adhesion and interfacial energy of the interfaces were calculated as descriptors of the interfacial properties, and then the mechanisms of the interfacial reactions taking place were characterized. Finally, a charge transfer analysis is presented, suggesting that, overall, the S-8 electrode will oxidize the electrolyte, whereas the fully discharged Li2S cathode will reduce it at different extents depending on the reactivity of the exposed facet.