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LiFePO4-Fe2P-C composite cathode: An environmentally friendly promising electrode material for lithium-ion battery

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posted on 2024-11-15, 02:27 authored by M Mahfuzur Rahman, Jiazhao WangJiazhao Wang, Rong Zeng, David Wexler, Hua LiuHua Liu
In this investigation, the synthesis strategy is involved the creation of LiFePO4-Fe2P-C composites with a porous conductive architecture, which includes distinct regions or clusters containing antiferromagnetic LiFePO4 in close proximity to ferromagnetic Fe2P. The microstructure is achieved by using a simple ultra-fast solvent assisted manual grinding method, combined with solid state reaction, which can replace the time-consuming high energy ball milling method. The crystalline structure, morphology, and electrochemical characterization of the synthesised product are investigated systematically. The electrochemical performance is outstanding, especially the high C rate. The composite cathode is found to display specific capacity of 167 mAh g-1 at 0.2 c and 146 mAh g-1 at 5 c after 100 cycles, respectively. At the high current density of 1700 mA g-1, it exhibits long-term cycling stability, retaining around 96 per cent of its original discharge capacity beyond 1000 cycles, which can meet the requirements of a lithium-ion battery for large-scale power applications. The obtained results have demonstrated that the fabrication of samples with strong and extensive antiferromagnetic and ferromagnetic interface coupling of LiFePO4/Fe2P provides a versatile strategy toward improving the electrochemical properties of LiFePO4 materials and also opens up a new window for material scientists to further study the new exchange bias phenomenon and its ability to enhance the electrochemical performance of lithium-ion battery electrode.

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Citation

Rahman, M., Wang, J., Zeng, R., Wexler, D. & Liu, H. K. (2012). LiFePO4-Fe2P-C composite cathode: An environmentally friendly promising electrode material for lithium-ion battery. Journal of Power Sources, 206 (May), 259-266.

Journal title

Journal of Power Sources

Volume

206

Pagination

259-266

Language

English

RIS ID

52512

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