新型锂离子电池薄膜的比较研究

M. Ikhsanudin
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摘要

锂离子电池的发展导致了高密度锂离子电池技术作为一种存储系统。实现锂离子电池高能量密度的方法是对其阳极进行修饰,即薄膜阳极。所用的阳极涂有厚度为10毫米的材料,增加了可容纳在一个电池中的阴极材料。本研究旨在分析用于薄膜锂离子电池的铜粉和LTO材料作为石墨的替代品,因为它们具有更高的容量,化学稳定性,快速充电技术(LTO),廉价和环保(铜粉)。XRD和FTIR测试表明,该材料具有良好的晶体结构,杂质含量较少。SEM结果表明,两种颗粒在单个颗粒的形状上都表现出均匀性,并且通过SEM- edx测试来检查两种材料中每种元素的含量。电化学测试结果表明,铜粉材料的比容量为144.82 mAh g-1,高于LTO (81.04 mAh g-1)。
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Comparative Study of Novelty Thin-films for Li-ion Batteries
The development of Li-ion batteries leads to high-density Li-ion battery technology as a storage system. to realize a Li-ion battery with a high energy density is to modify its anode, called a thin-film anode. The anode used is coated with a material thickness of 10 mm, increasing the cathode material that can be accommodated in one cell. This study aimed to analyze the Cu-powder and LTO materials used in Thin-film Li-ion batteries as a substitute for graphite because they offer higher capacity, chemical stability, fast charging technology (LTO), cheap, and environmentally friendly (Cu-powder). Based on XRD and FTIR tests, the material has a good crystal structure, and not many impurities are still contained in it. The SEM results showed that both particles showed uniformity in the shape of a single particle and were strengthened by the SEM-EDX test to review the quantity of each element present in the two materials. The electrochemical test results showed that Cu-powder material was better, with a specific capacity of 144.82 mAh g-1, higher than LTO (81.04 mAh g-1).
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