Ab Initio Study of the Interface of the Solid-State Electrolyte Li 9 N 2 Cl 3  with a Li-Metal Electrode

Abstract

© The Author(s) 2019. Ab initio molecular dynamics study of an electrochemical interface between a solid-state-electrolyte Li9N2Cl3 and a Li-metal is performed to analyze interphase formation due to electrochemical instability. An external electric field is applied to emulate the interface under charging conditions. At open circuit, we observed electrochemical stability at both sides of the interface, without electrolyte decomposition, or new phase formation, in good agreement with reported experiments. However, a structural re-accommodation takes place at both sides of the interface. Some oxidation of the surface Li-atoms takes place when Cl and N anions capture Li from the metal to complete octahedral structures, a Bader charge and electron density analyses explain the difference between Cl and N behavior. At the interface with the Li9N2Cl3 (002) facet, the larger negative charge on low-coordinated N atoms is able to retain more Li atoms than the Cl atoms do. At charging conditions applying an external electric field (0.5 V/Å), no major changes are observed in atomic diffusion or structural changes at the interphase; however, the main difference is the change of the Li-metal crystal structure. Due to migration of Li from the metal anode to the electrolyte, vacancies are created on the anode, causing a structural re-arrangement at the anode surface.