Litcius/Paper detail

Theoretical Design of Defects as a Driving Force for Ion Transport in <scp>Li<sub>3</sub>OBr</scp> Solid Electrolyte

Xingyun Luo, Yanlu Li, Xian Zhao

2023Energy & environment materials12 citationsDOIOpen Access PDF

Abstract

Due to ever‐increasing concerns about safety issues in using Li ionic batteries, solid electrolytes have extensively explored. The Li‐rich anti‐perovskite Li 3 OBr has been considered as a promising solid electrolyte candidate, but it still suffers challenges to achieve a high ionic conductivity owing to the high intrinsic symmetry of the crystal lattice. Herein, we presented a design strategy that introduces various point defects and grain boundaries to break the high lattice symmetry of Li 3 OBr crystal, and their effect and microscopic mechanism of promoting the migration of Li‐ion were explored theoretically. It has been found that are the dominant defects responsible for the fast Li‐ion diffusion in bulk Li 3 OBr and its surface, but they are easily trapped by the grain boundaries, leading to the annihilating of the Frenkel defect pair and thus limits the diffusion at the grain boundaries. The defect near the grain boundaries can effectively drive across the grain boundary, thereby converting the carrier of Li + migration from in the bulk and surface to at the grain boundary, and thus improving the ionic conductivity in the whole Li 3 OBr crystal. This work provides a comprehensive insight into the Li + transport and conduction mechanism in the Li 3 OBr electrolyte. It opens a new way of improving the conductivity for all‐solid‐state Li electrolyte material through the defect design.

Topics & Concepts

Grain boundaryIonic conductivityElectrolyteFast ion conductorMaterials scienceChemical physicsIonic bondingCrystallographic defectConductivityIonCrystal (programming language)Grain boundary diffusion coefficientDiffusionCrystallographyChemistryThermodynamicsMetallurgyPhysical chemistryMicrostructureElectrodePhysicsOrganic chemistryProgramming languageComputer scienceAdvanced Battery Materials and TechnologiesAdvancements in Battery MaterialsThermal Expansion and Ionic Conductivity
Theoretical Design of Defects as a Driving Force for Ion Transport in <scp>Li<sub>3</sub>OBr</scp> Solid Electrolyte | Litcius