Regulating Li2S Deposition by Ostwald Ripening in Lithium-Sulfur Batteries

The lithium-sulfur (Li-S) batteries have attracted tremendous attention from both academia and industry for their high energy density and environmental benignity. However, the cell performance suffers from the passivation of the conductive matrix caused by uncontrolled lithium sulfide (Li2S) deposition. Therefore, regulation of Li2S deposition is essential to advanced Li-S batteries. In this work, the role of temperature in regulating Li2S deposition is comprehensively investigated. At room temperature (25 degrees C), Li2S exhibits a two-dimensional (2D) growth mode. The dense and insulating Li2S film covers the conductive surface rapidly, inhibiting the charge transfer for subsequent polysulfide reduction. Consequently, the severe passivation of the conductive surface degrades the cell performance. In contrast, three-dimensional (3D) Li2S is formed at a high temperature (60 degrees C) because of a faster Ostwald ripening rate at an elevated temperature. The passivation of the conductive matrix is mitigated effectively, and the cell performance is enhanced significantly, thanks to the formation of 3D Li2S. Ostwald ripening is also valid for Li-S cells under rigorous conditions. The cell working at 60 degrees C achieves a high specific capacity of 1228 mA h g(-1) under the conditions of high S loading and a lean electrolyte (S loading = 3.6 mg cm(-2), electrolyte/sulfur ratio = 3 mu L mg(-1)), which is substantially higher than that at 25 degrees C. This work enriches the intrinsic understanding of Li2S deposition in Li-S batteries and provides facile strategies for improving the cell performance under practical conditions.

Automated summary

The lithium-sulfur (Li-S) batteries have attracted attention for their high energy density and environmental benignity. This study investigated the role of temperature in regulating Li2S deposition and found that forming three-dimensional (3D) Li2S at high temperature effectively mitigates the passivation of the conductive matrix and significantly enhances the cell performance.