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LiFePO_4锂离子电池正极材料的电化学性能 被引量:16

Electrochemical properties of LiFePO_4/C for cathode materials of lithium ion batteries
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摘要 以碳凝胶作为碳添加剂, 采用固相法制备了复合型LiFePO4 /C锂离子电池正极材料。研究了不同掺碳量对样品性能的影响。利用X射线衍射仪、扫描电镜和碳硫(质量分数)分析方法对所得样品的晶体结构、表面形貌、含碳量进行分析研究。结果表明: 样品中的碳含量(质量分数)分别为 0%、5%、10%、22%, 所得样品均为单一的橄榄石型晶体结构, 碳的加入使LiFePO4 颗粒粒径减小。另外, 碳分散于晶体颗粒之间, 增强了颗粒之间的导电性。合成样品的电化学性能测试结果表明, 掺碳后的LiFePO4 放电比容量和循环性能都得到显著改善。其中,含碳量为 22%的LiFePO4 /C在 0 1C倍率下放电, 首次放电容量达 143 4mA·h/g, 充放电循环 6次后电容量为142 7mA·h/g, 容量仅衰减 0 7%。 LiFePO_4/C composite obtained with carbon gel as carbon droped were prepared by solid-state reaction. The crystalline structure, morphology of particles, carbon contents were analyzed by X-ray diffraction, scanning electromicroscopy and carbon/sulfur determinator. The resulting carbon contents in these samples are 0%, 5%, 10%, 22%, respectively . The results of X-ray diffraction show that the LiFePO_4/C is pure olivine-type phase. SEM micrographs confirmed that the addition of the carbon reduces the LiFePO_4 grain size.The carbon is dispersed between the grains, ensuring a good electronic contact. Electrochemical tests show that the material obtained by adding carbon gives enhanced performance in term of improved practical capacity and cycleability. The first specific discharge capacities of the LiFePO_4/C coated with about 22% carbon is 143.4mA·h/g, after 6 times cycling the discharge capacities is 142.7mA·h/g. The capacity fade is about 0.7%.
作者 张宝 罗文斌 李新海 王志兴
机构地区 中南大学冶金科学与工程学院
出处 《中国有色金属学报》 EI CAS CSCD 北大核心 2005年第2期300-304,共5页 The Chinese Journal of Nonferrous Metals
基金 国家自然科学基金资助项目(50302016)
关键词 锂离子电池 正极材料 磷酸铁锂 碳凝胶 Li-ion battery cathode material lithium iron phosphate carbon gel
分类号 TM912.9 [电气工程—电力电子与电力传动]
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参考文献22

  • 1Thackeray M M, David W I F, Goodenough J B .Structural characterization of the lithium ion oxides LixFe3 O4 and Lix Fe2O3 (0<x<2) [J]. Mat Res Bull,1982, 17: 785-800.
  • 2Thackeray M M, David W I F, Goodenough J B.High-temperature lithiati on of α-Fe2 O3: a mechanistic study[J]. J Solid State Chem, 1984, 55: 280-282.
  • 3Pernet M, Strobl P, Bonnet B, et al. Strctural and electrochemical study of lithium insertion into γ-Fe2 O3[J]. Solid State Ionics, 1993, 64:259-263.
  • 4Islam M S, Catlow C R A. Lithium insertion into Fe3O4[J]. J Solid State Chem, 1988, 77:180-182.
  • 5de Picciotto L A, Thackeray M M. Lithium insertion into the spinel LiFe5 O8[J]. Mat Res Bull, 1986, 21:583-589.
  • 6Chen C J, Greenblatt M, et al. Lithium insertion into spinel ferrites[J]. Solid State Ionics, 1986, 18-19:838-845.
  • 7Chen C J, Greenblatt M, Waszczak J V. Lithium insertion compounds of LiFe5 O8, Li2FeMn3 O8 and Li2 ZnMn3 O8[J]. J Solid State Chem, 1986, 64:240-246.
  • 8Frong R, Dahn J R, Jones C H W. Electrochemistry of pyrite-based cathodes for ambinent temperature lithium batteries[J]. J Electrochem Soc, 1989, 136:3206-3211.
  • 9Sakaebe H, Higuchi S, Kanamura K, et al. Discharge and charge characteristics of amorphous FeOOH including aniline[J]. J Electrochem Soc, 1995, 142: 360.
  • 10Hikari S, Shunich H, Fujimoto K K, et al . Electrochemical properties of FeOCI derivatives prepared by the reaction of FeOCl intercalated with 2, 2-bithiophene and H2O[J]. Solid State Ionics, 2002, 79:234-240.

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中国有色金属学报
2005年 第2期

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