Abstract
In this study, First-Principles simulations were utilized to investigate the structural characteristics and address some of the stability issues of the solid electrolyte material Li4PS4I. The computational results indicate that unlike most ion-conducting systems, Li4PS4I does not exhibit a fully ordered phase that is stable at ambient conditions. Instead, the material prefers a disordered configuration at room temperature, and the configurational entropy arising from the disordered nature of the material plays a critical role in stabilizing the material. Additionally, a plausible metastable fully ordered phase of the material was identified, which was used to examine the structural properties and interface stability with Li anode of the material. Our analysis of the interface stability revealed that Li4PS4I is likely to react with Li anode, but the reaction is limited to the surface layers of the material. Furthermore, the comparison of the idealized interfaces with Li anode of Li4PS4I with the analogue γ − Li3PS4 suggests that less P-S bonds are broken for Li4PS4I, which is attributed to the presence of Iodine on the surface. This finding supports the argument that the incorporation of Lithium iodine into sulfide-based electrolytes enhances their stability when in contact with a Li anode.
Funder
Khalifa University of Science, Technology and Research
Publisher
The Electrochemical Society
Subject
Materials Chemistry,Electrochemistry,Surfaces, Coatings and Films,Condensed Matter Physics,Renewable Energy, Sustainability and the Environment,Electronic, Optical and Magnetic Materials