Dopamine-Derived Graphite-Like Hard Carbon Materials for High-Performance Li+ Ions Storage

Xianfa Rao, Baobao Li, K. Lei, Yitao Lou, Lixia Zhang, Longhai Weng, Long Chen, Xuanbo Shi, Shengwen Zhong, Baotong Liu, Li Wang
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Abstract

Graphite anode material is easily powdered under large currents, resulting in a short circuit inside the battery, causing serious safety hazards. Therefore, it is necessary to study a negative electrode material, increase the diffusion channel of lithium ions, increase the layer spacing, reduce the transmission distance, effectively weaken the lithium-ion deposition, and improve the cycle life. A novel organic hard carbon material was prepared by calcining dopamine hydrochloride (DA) at three temperatures. Under the inert atmosphere of 950 °C, the material is fully carbonized, the lattice spacing is 0.367 nm, and it has good lithium-ion transmission activity. After assembling into a battery, after 2000 charge-discharge tests at a high rate of 10C, the charging specific capacity is still 103.3mAh g-1, and the CE remains 101.4%. Dopamine hard carbon anode materials exhibit excellent specific capacity and cycle properties, providing new ideas to support the rapid charging and discharging of hard carbon anode materials.
用于高性能Li+离子存储的多巴胺衍生类石墨硬碳材料
石墨负极材料在大电流作用下容易粉末状,导致电池内部短路,造成严重的安全隐患。因此,有必要研究一种负极材料,增加锂离子的扩散通道,增加层间距,减小传输距离,有效削弱锂离子沉积,提高循环寿命。以盐酸多巴胺(DA)为原料,在三种温度下煅烧制备了一种新型有机硬碳材料。在950℃惰性气氛下,材料完全碳化,晶格间距0.367 nm,具有良好的锂离子透射活性。组装成电池后,在10C的高倍率下进行2000次充放电测试,充电比容量仍为103.3mAh g-1, CE仍为101.4%。多巴胺硬碳负极材料具有优异的比容量和循环性能,为支持硬碳负极材料的快速充放电提供了新的思路。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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