Electrochemical and Mechanical Evolution of Sulfide-Based Solid Electrolytes: Insights from Operando XPS and Cell Pressure Measurements.
Valerie Siller, Linfeng Xu, Laurent Castro, Aurélie Guéguen, Mario El Kazzi
Abstract
Open AccessUnderstanding the electrochemical and mechanical behavior of solid electrolytes beyond their electrochemical stability window is crucial for enabling high energy density all-solid-state batteries. Accordingly, this work systematically studies a model working electrode of Li3PS4, ball milled with vapor grown carbon fiber (VGCF). Operando X-ray photoelectron spectroscopy can identify and quantify the potential-dependent redox byproducts, their reversibility, and electrical properties, while operando cell pressure measurements correlate these with volume changes and mechanical instability. The study examines voltages up to 5.0 V and down to -0.05 V versus Li/Li+, mimicking cathode and anode cycling. It demonstrates that within the 2.4-5.0 V region, Li3PS4 oxidation byproducts are primarily polysulfides composed of bridging sulfurs (P-S-S-P) between PS4 3- units, free of elemental sulfur (S0), and electrically conductive. The Li3PS4 oxidation process occurs at 2.8 V during first charge and ends at 3.4 V, with volume shrinkage at the VGCF interface. During reduction (2.4 to -0.05 V), polysulfides convert reversibly to Li3PS4 between 1.9 and 1.7 V, then to Li2S and LinP (0 ≤ n ≤ 3) between 1.9 and 0.6 V, causing volume expansion and the transition to an electrically insulating interphase. Below 0.6 V, Li2O formation dominates without further evolution of Li2S or LinP.