Atomic Insights into the Oxidative Degradation Mechanisms of Sulfide Solid Electrolytes

TL;DR

This study combines experimental, computational, and machine learning techniques to reveal atomic-scale oxidative degradation mechanisms in sulfide solid electrolytes, providing insights for improved solid-state battery stability.

Contribution

It presents the first atomic-scale understanding of oxidative degradation in sulfide electrolytes, linking spectral fingerprints to structural changes and interfacial impedance.

Findings

Degradation involves S-S bond formation and tetrahedral distortion.

Spectral fingerprints correlate with structural evolution during delithiation.

Degradation increases interfacial impedance, affecting battery performance.

Abstract

Electrochemical degradation of solid electrolytes is a major roadblock in the development of solid-state batteries, and the formed solid-solid interphase (SSI) plays a key role in the performance of solid-state batteries. In this study, by combining experimental X-ray absorption spectroscopy (XAS) measurements, first-principles simulations, and unsupervised machine learning, we have unraveled the atomic-scale oxidative degradation mechanisms of sulfide electrolytes at the interface using the baseline Li3PS4 (LPS) electrolyte as a model system. The degradation begins with a decrease of Li neighbor affinity to S atoms upon initial delithiation, followed by the formation of S-S bonds as the PS4 tetrahedron deforms. After the first delithiation cycle, the PS4 motifs become strongly distorted and PS3 motifs start to form. Spectral fingerprints of the local structural evolution are identified, which correspond to the main peak broadening and the peak shifting to a higher energy by about 2.5 eV in P K-edge XAS and a new peak emerging at 2473 eV in S K-edge XAS during delithiation. The spectral fingerprints serve as a proxy for the electrochemical stability of phosphorus sulfide solid electrolytes beyond LPS, as demonstrated in argyrodite Li6PS5Cl. We observed that the strong distortion and destruction of PS4 tetrahedra and the formation of S-S bonds are correlated with an increased interfacial impedance. To the best of our knowledge, this study showcases the first atomic-scale insights into the oxidative degradation mechanism of the LPS electrolyte, which can provide guidance for controlling macroscopic reactions through microstructural engineering and, more generally, can advance the rational design of sulfide electrolytes.