揭示锂硫电池中碘化锂介导的界面过程:原位原子力显微镜研究

Yuan Li , Zhen-Zhen Shen , Gui-Xian Liu , Rui Wen
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引用次数: 1

摘要

在各种储能装置中,锂硫电池因其较高的理论能量密度和比容量而受到广泛关注。为了提高锂硫电池的性能并实现其实际应用,揭示循环过程中电极/电解质界面的动态演变和反应机理是至关重要的。然而,尽管付出了巨大的努力,但细节仍然不为人所知,这需要更多的原位和非破坏性成像表征。本文将原子力显微镜与电化学工作站相结合,动态可视化界面过程的形态演变和结构变化,揭示了锂硫电池中碘化锂介导的界面反应。现场测试结果表明,在充电过程中,电极表面包覆了一层由碘元素和聚醚组成的网状层,并添加了碘化锂添加剂,可以有效地防止不溶性硫化物在表面聚集,提高锂硫电池的循环性能。这些发现揭示了界面机制的新亮点,并为未来开发更好的锂硫电池电解质建立了设计思路。
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Unraveling the lithium iodide-mediated interfacial process in lithium-sulfur batteries: An in situ AFM study

Among various energy storage devices, lithium-sulfur batteries have attracted widespread attention due to their high theoretical energy density and specific capacity. To improve the performance and realize practical applications of lithium-sulfur batteries, it is crucial to unravel the dynamic evolution and reaction mechanism at the electrode/electrolyte interfaces during cycling. Nevertheless, the details are still not well known despite generous efforts, which need more in situ and non-destructive imaging characterizations. Herein, we have combined AFM with an electrochemical workstation to dynamically visualize the morphological evolution and structural changes of the interfacial process, which reveals the lithium iodide-mediated interfacial reactions in lithium-sulfur batteries. In situ measurements showed that the electrode surface was coated by a reticular layer consists of elemental iodine and polyether with lithium iodide additive during charging, which could effectively prevent insolube sulfides from gathering on the surface and improve the cycling performances of lithium-sulfur batteries. These findings shed new light on the interfacial mechanism and establish design ideas for the future development of better electrolytes for lithium-sulfur batteries.

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