[1]孙昊,刘涛,杜晓辉,等.葡萄糖作碳源时碳包覆量对LiFePO4及其锂电池性能的影响[J].石化技术与应用,2024,6:431-435.
SUN Hao,LIU Tao,DU Xiao-hui,et al.Effect of carbon-coated amount on performances of FePO4 and its lithium battery under glucose as carbon source[J].Petrochemical technology & application,2024,6:431-435.
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葡萄糖作碳源时碳包覆量对LiFePO4及其锂电池性能的影响(PDF)
《石化技术与应用》[ISSN:1009-0046/CN:62-1138/TQ]
- 期数:
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2024年6期
- 页码:
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431-435
- 栏目:
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- 出版日期:
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2024-11-10
文章信息/Info
- Title:
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Effect of carbon-coated amount on performances of FePO4 and its lithium battery under glucose as carbon source
- 文章编号:
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1009-0045(2024)06-0431-05
- 作者:
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孙昊; 刘涛; 杜晓辉; 任世宏; 孙书红; 方华; 赵鸣芝; 张丽桦
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中国石油石油化工研究院 兰州化工研究中心,甘肃 兰州 730060
- Author(s):
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SUN Hao; LIU Tao; DU Xiao-hui; REN Shi-hong; SUN Shu-hong; FANG Hua; ZHAO Ming-zhi; ZHANG Li-hua
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Lanzhou PetroChemical Research Center,Petrochemical Research Institute,PetroChina,Lanzhou 730060,China
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- 关键词:
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LiFePO4; 葡萄糖; 碳包覆量; 前驱体; 锂离子电池; 充放电比容量; 充放电倍率; 电化学性能
- Keywords:
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lithium iron phosphate; glucose; carbon-coated amount; precursor; lithium-ion battery; specific capacity of charge-discharge; C-rate ; electrochemical performance
- 分类号:
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TQ 150.7
- DOI:
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10.19909/j.cnki.ISSN1009-0045.2024.06.0431
- 文献标识码:
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B
- 摘要:
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首先,以Li2CO3,NH4H2PO4,Fe(NO3)3·9H2O,葡萄糖、无水乙醇为原料,采用溶胶凝胶法合成FePO4前驱体,再采用碳热还原法制备了碳包覆的LiFePO4 (简称为LFP/C);然后,考察了葡萄糖作为碳源时碳包覆量对LFP/C相纯度、粒径、形貌等的影响,并评价了LFP/C作为正极的锂离子电池的电化学性能。结果表明:当碳包覆量过少或过多时,均不利于LFP/C的高温成型过程,在Fe∶Li∶C(摩尔比)为1.00∶1.02∶0.15时,制得的LFP/C-2纯度更高、分散性更好、颗粒更均匀;以LFP/C-2作为正极制作的锂离子电池,在0.2 C充放电倍率下的初始充放电比容量分别为152.20,132.73 mAh/g,首次充放电效率达91.20%,并且在10.0 C充放电倍率下的充放电比容量能保持在94.70 mAh/g。
- Abstract:
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Firstly,FePO4 precursor was synthesized by sol-gel method with Li2CO3, NH4H2PO4,Fe(NO3)3·9 H2O,glucose and anhydrous ethanol as raw materials,and then carbon-coated lithium iron phosphate (hereinafter referred to as LFP/C) was prepared by carbothermal reduction method. Then the effects of the amount of glucose as a carbon source on the phase purity and particle size and morphology of LFP/C were investigated. The electrochemical performance of lithium-ion batteries with LFP/C as positive electrode was evaluated. The results showed that when the carbon-coated amount was too little or too much, it was not favorable for the high-temperature forming process on LFP/C. When the molar ratio of Fe∶ Li∶ C at 1.00∶1.02∶0.15,the LFP/C-2 obtained had higher purity,better dispersibility,and more uniform particles. The lithium-ion battery,which made from LFP/C-2 as the positive electrode,had the initial specific capacity of charge-discharge at 152.20,132.73 mAh/g on the premise of 0.2 C-rate (referred to the ratio of current to nominal capacitance of a battery when it was charged and discharged. ),respectively, and the initial charge- discharge efficiency was up to 91.20%. Meanwhile,the specific capacity of charge-discharge could be maintained at 94.70 mAh/g at 10.0 C-rate.
参考文献/References
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更新日期/Last Update:
2024-11-10