材料科学
电解质
硫黄
渗透(认知心理学)
离子键合
储能
离子电导率
电化学
复合数
纳米技术
化学工程
氧化还原
快离子导体
相(物质)
离子
碘
动力学
电极
无机化学
能量密度
极限(数学)
电化学储能
渗流理论
离子液体
作者
Jingui Yang,Ruizhuo Zhang,Ramon Zimmermanns,Mareen Schaller,Sylvio Indris,Jaehoon Choi,Simon Fleischmann,Torsten Brezesinski,Florian Strauss
标识
DOI:10.1002/adma.202513204
摘要
ABSTRACT All‐solid‐state lithium‐sulfur batteries (ASSLSBs) hold great promise for next‐generation electrochemical energy storage due to sulfur's high theoretical specific capacity and low cost. However, sluggish sulfur conversion kinetics and severe volume variations during cycling, as well as poor ionic percolation in composite cathodes, limit their practical viability. To overcome these challenges, we herein introduce solid electrolytes of nominal composition Li 10.5− x Si 1.5 P 1.5 S 12− x I x (with x = 0, 0.2, 0.4), possessing high ionic conductivities of ≥ 7 mS cm −1 at room temperature. We show that increasing iodine content alters the phase composition and triggers reversible redox activity in these materials. If implemented as catholytes, this enables very fast sulfur conversion kinetics, ultimately leading to ASSLSBs with exceptional performance. The cells achieve 86% sulfur utilization at a rate of C/2 and at 45°C and offer high‐rate capability by delivering 1175 mAh g sulfur −1 at 5C and 590 mAh g sulfur −1 at 15C. Furthermore, the synergistic effects of ionic percolation and redox‐activity enable record areal capacities up to 14 mAh cm −2 with a sulfur loading of 10 mg cm −2 . Taken together, our findings provide new strategies for designing redox‐active catholytes for application in advanced ASSLSBs and further strengthen the redox‐mediating role of iodine therein.
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