Lu Gao, Xia Liu, Lei Li, Nanping Deng, Weimin Kang, Bowen Cheng
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引用次数: 0
Abstract
Among optimization strategies for solving the poor ion transport ability and electrolyte/electrode interface compatibility problems of lithium (Li)-based batteries, halogen elements, such as fluorine (F) and iodine (I), have gradually occupied an important position because of their superb electronegativity, oxidizability, ionic radius, and other properties. The study commences by outlining the shared mechanism by which F and I enhance solid-state lithium metal batteries' electrochemical performance. In particular, F and I can considerably improve ion transport capacity through chemical means such as intermolecular interactions and halogenation reactions. Furthermore, the utilization of F and I significantly enhances the stability of the electrolyte/electrode interface via physical strategies, encompassing doping techniques, the application of surface coatings, and the fabrication of synthetic intermediate layers. Subsequently, the characteristics of F and I used in Li-based batteries are elaborated in detail, focusing on the fact that F can provide additional energy density as an anode material but by different mechanisms. Additionally, I can considerably activate dead lithium at the negative electrode, and F can act as a new carrier. Finally, a rational concept of the synergistic effect of F and I is proposed and the feasibility of F–I bihalide solid electrolytes is explored.
在解决锂(Li)基电池离子传输能力差和电解质/电极界面兼容性问题的优化策略中,卤素元素,如氟(F)和碘(I),因其超强的电负性、氧化性、离子半径等特性,逐渐占据了重要地位。本研究首先概述了 F 和 I 增强固态锂金属电池电化学性能的共同机制。特别是,F 和 I 可通过分子间相互作用和卤化反应等化学手段显著提高离子传输能力。此外,通过物理策略,包括掺杂技术、表面涂层的应用和合成中间层的制造,F 和 I 的使用可显著提高电解质/电极界面的稳定性。随后,详细阐述了锂基电池中使用的 F 和 I 的特性,重点是 F 作为阳极材料可以通过不同的机制提供额外的能量密度。此外,I 可以显著激活负极上的死锂,而 F 则可以充当新的载体。最后,提出了 F 和 I 协同效应的合理概念,并探讨了 F-I 双卤化物固体电解质的可行性。
期刊介绍:
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