锂离子电池石墨负极的改性

Xiaohan Xia
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引用次数: 0

摘要

传统的化石能源正在被低碳清洁能源所取代,而锂电池因其高能量密度和功率密度而受到广泛关注和应用。石墨以其优异的电化学性能成为最常用的负极材料。由于石墨的理论储锂容量仅为 372 mAh/g,因此石墨负极锂电池存在电解液相容性差、体积膨胀率高等问题。为了提高石墨负极材料的综合性能,许多研究人员致力于石墨负极的改性研究。本文主要介绍石墨负极的三种主要改性方法。从球化处理、表面涂层和元素掺杂三个方面总结了石墨改性在提高锂电池性能方面的应用研究进展。球化处理和表面涂层能有效改善材料界面的电化学性能,但难以提高材料界面的能量密度。掺杂改性可以提高能量密度,但不能做到均匀稳定。石墨负极的改性和改良技术仍有待开发。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Modification of graphite anode for lithium ion battery
Traditional fossil energy is being replaced by low-carbon clean energy, and lithium batteries have obtained extensive attention and are widely used for their high energy density and power density. Graphite is the most commonly used anode material for its excellent electrochemical performance. Since the theoretical lithium storage capacity of graphite is only 372 mAh/g, the lithium battery with graphite anode has problems such as poor electrolyte compatibility and a high volume expansion rate. Many researchers have devoted themselves to the modification of graphite anode to improve the comprehensive performance of graphite anode materials. This paper focuses on three main modification methods of graphite anodes. The application research progress of graphite modification on the improvement of lithium batteries performance was summarized from the aspects of spheroidization treatment, surface coating, and element doping. Spheroidization treatment and surface coating can effectively improve the electrochemical properties of the material interface, but it is difficult to increase the energy density of the material interface. Doping modification can improve energy density, but it cannot be uniform and stable. The modification and improvement technology of graphite anode still needs to be developed.
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