Unlocking the Ion Migration in Solid-State Electrolytes via Path Entropy (2412.07115v1)

Abstract: Promoting ionic diffusion by reducing activation energy, as a thermally activated process following the Arrhenius relation, is a fundamental principle in designing materials for electrochemical batteries. However, this scenario is constrained by the enthalpy-entropy compensation mechanism (Meyer-Neldel Rule, MNR), which is ubiquitously observed in biological process and chemical reactions. This sets a limitation of promoting ion transport by reducing activation enthalpy. Notably, certain solid-state electrolytes characterized by disordering or degenerate saddle states exhibit anomalous behaviours and disobey MNR, suggesting the existence of an elusive source of entropy. Herein we propose the concept of path entropy (Sp) governs kinetic process in dense and mobile ionic systems such as lithium diffusion in solid-state electrolytes. By integrating Markov state method, well-tempered metadynamics, and machine learning-based softness analysis, we elucidate the intricate relationship between fast ionic hopping and microscopic local environments in inorganic thiophosphates. The Sp accounts for a strong fluctuation of free energy landscape perceived by Li cations and enables an assessment of their collective diffusion behaviour as well. A unified framework is established for handling time-evolved and group-collective ionic kinetics, which exploits pathway frustration, transcending common "static" scenario in traditional entropy-driven approach based on compositional multiplicity. This provides a new dimension for connecting structural disorder and the freedom of ionic diffusion pathways, suitable for a wide range of ionic-driven applications such as battery, superionic conductors and neuromorphic devices.