APPLICATION OF MODIFIED CONDUCTIVE ADDITIVES AND AQUEOUS BINDERS IN POSITIVE ELECTRODES BASED ON LITHIUM IRON PHOSPHATE FOR LITHIUM ION BATTERIES

A.B. Abdrakhmanova, B.T. Kuderina, N. Omarova, A. Sabitova
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Abstract

Positive electrodes play a significant role in operation of lithium-ion batteries. The inactive constituents of the electrode coating, electrically conductive additive and binder, are key components for efficient operation of active material.Therefore, minimizing the toxicity of some and the synthesis or modification of others remain an urgent topic for increasing the energy intensity of lithium-ion batteries, which is the main goal of this work. The purpose: Synthesis and modification of nanostructured carbon electrically conductive additives and the study of their influence on the specific characteristics of the electrode in combination with water-soluble polymers. Results.During the research, the optimal compositions of the positive electrode were found: 1) using aqueous polymers, 2) with the addition of synthesized graphene oxide obtained by the Hummers method; 3) with the addition of modified carbon nanotubes obtained by the Hummers method. Conclusion. Graphene oxide synthesized by the Hummers method and carbon nanotubes reduced by the same method give a discharge specific capacity of more than 150 mAh/g and 140 mAh/g, respectively, with an active material theoretical capacity of 160-170 mAh/g, those using them instead of commercial conductive additives can significantly improve the specific characteristics of positive electrodes. This is due to an increase in the kinetics of lithium ion transfer inside the active material due to many structural defects due to synthesis, in addition, they are better dispersed in water, and it is also possible to obtain thick coating layers.
改性导电添加剂及水性粘合剂在锂离子电池磷酸铁锂正极中的应用
正极在锂离子电池的工作中起着重要的作用。电极涂层的非活性组分,导电添加剂和粘结剂,是有效运行活性物质的关键组分。因此,降低某些物质的毒性和合成或修饰其他物质仍然是提高锂离子电池能量强度的紧迫课题,这也是本工作的主要目标。目的:纳米结构碳导电添加剂的合成与改性,研究其与水溶性聚合物结合对电极特性的影响。结果。在研究过程中,找到了最佳的正极组成:1)使用水性聚合物,2)添加通过Hummers方法合成的氧化石墨烯;3)加入Hummers法得到的改性碳纳米管。结论。采用Hummers方法合成的氧化石墨烯和采用相同方法还原的碳纳米管的放电比容量分别大于150 mAh/g和140 mAh/g,活性材料理论容量为160-170 mAh/g,用它们代替商用导电添加剂可以显著提高正极的比容量。这是由于由于合成的许多结构缺陷,使活性材料内部锂离子转移动力学增加,此外,它们在水中分散得更好,并且也有可能获得较厚的涂层。
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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