作为锂离子电池中高倍率高性能负极材料的 C/SiO2/Graphene 纳米片的电化学特性

Energy Storage Pub Date : 2024-09-24 DOI:10.1002/est2.70043
Yen Kim Nguyen Chuong, Quynh Nhu Nguyen, Man Van Tran, Phuoc Anh Le, Phung Loan My Le, Viet Bac T. Phung, Phat Tan Vu
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引用次数: 0

摘要

锂离子电池是现代社会的重要电源,特别是主要用于驱动电子设备、电动汽车(EV)和未来的固定储能设备。对于电动汽车和大规模应用来说,电池成本仍然是一个挑战,这就不断需要开发低成本和丰富元素的材料,以实现电池的可持续生产。从稻壳中提取的二氧化硅因其原料来源的优势和成本效益而成为一种前景广阔的负极材料。然而,这种材料的电子导电率低、锂离子扩散率差,因此不适合快速充电或高功率应用。为了克服这些挑战,人们引入了石墨烯纳米片作为导电添加剂,以增强电子导电性并优化电池中的锂离子扩散。在这项研究中,利用超声波方法,使用从稻壳中提取的 C/SiO2 和石墨烯纳米片制造出了 C/SiO2/ 石墨烯复合材料。石墨烯含量为 85 wt%的混合物在所研究的各种比例中表现出卓越的电化学性能,具有出色的循环性能(在 0.1 A g-1 下循环 50 次后,容量保持率为 86.18%,达 305 mAh g-1)和令人印象深刻的速率能力(在 2.0 A g-1 的高电流下,容量保持率为 69.9 mAh g-1,几乎是裸 C/SiO2 的三倍)。XPS 和 GITT 分析证实,C/SiO2/石墨烯电极上的固体电解质相间层 (SEI) 由于含有更高的 LiF-Li2CO3 而更稳定、导电性更强,石墨烯的高表面积增强了锂的扩散。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Electrochemical Properties of C/SiO2/Graphene Nanoplatelets as High-Rate Performance Anode Material in Li-Ion Batteries

Lithium-ion batteries are vital power sources for modern society, especially mainly powered electronic devices, electric vehicles (EVs), and future stationary energy storage. Battery cost is still challenging for EVs and large-scale applications that continuously require the development of low-cost and abundant elements-based materials for sustainable battery manufacturing. SiO2 derived from rice husks emerges as a promising anode material owing to its advantageous raw source and cost-effectiveness. However, the material's low electronic conductivity and poor lithium-ion diffusion rate make it unsuitable for fast-charging or high-power applications. To overcome these challenges, graphene nanoplatelets have been introduced as a conducting additive to enhance electronic conductivity and optimize lithium diffusion in the battery. In this research, an ultrasonic method was utilized to create a composite of C/SiO2/graphene using C/SiO2 derived from rice husk and graphene nanoplatelets. The mixture containing 85 wt% of graphene exhibited superior electrochemical performance among the investigated ratios with excellent cycling performance (305 mAh g−1 with capacity retention of 86.18% after 50 cycles at 0.1 A g−1) and an impressive rate capability (69.9 mAh g−1 at a high current of 2.0 A g−1, nearly three times higher than the bare C/SiO2). XPS and GITT analysis confirmed that the solid electrolyte interphase (SEI) layer on the C/SiO2/graphene electrode was more stable and conductive due to higher LiF-Li2CO3 content, which enhanced the lithium diffusion from the graphene's high surface area.

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