锂离子电池碳负极中边缘碳及表面碳原子含量的理论计算被引量：2

Theoretical calculation of fraction of carbon atoms on surface and edge for carbon anode of lithium ion battery

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摘要通过理论分析与计算得到边缘碳及表面碳原子含量的表达式。分析了石墨微晶结构与成键特征,研究了石墨微晶中边缘碳原子与基平面碳原子的电化学特性。结果表明:边缘碳原子比基平面碳原子更易于与其他原子或基团形成较为稳固的联接,电化学反应活性较高;在首次充电过程中,边缘碳原子附近电解质的分解与SEI膜成膜反应速度较快,有利于形成联接较为紧密的SEI膜;建立了紧密堆砌的正六棱柱颗粒模型,推导出理想石墨中边缘碳原子及表面碳原子含量与微晶参数、颗粒尺寸之间的关系式。通过引入适当因子,修正了实际石墨颗粒与理想石墨在结构、形貌、孔隙率等方面的差别,得到的表达式可适用于石墨、无定形碳及改性碳等多种碳材料碳原子含量的计算。 The fractions of carbon atoms on the surface and edge were obtained by theoretical analysis and calculation. The electrochemical characteristics of carbon atoms on the edge and basal plane were determined by analyzing structure of graphite crystal and bond of different carbon atoms. The results show that the atoms on the edge are more active for electrochemical reactions and tend to form stable bond with other atoms and groups. In the initial charge, the electrolyte decomposition and formation of solid electrolyte interface （SEI） on the edge are faster, and tighter SEI is formed there. A hexagonal close-packed model for graphite particle was developed. The fraction of carbon atoms on the surface and edge was derived in expression of crystallographic parameters and particle size. The practical graphite particle and the ideal graphite have some difference in structure, appearance and micro-cavity, which may cause the fractions of surface carbon and edge carbon change, and some correctional factors have been introduced to revise the difference. The revised expression is suitable for calculation on fraction of carbon atoms of carbon materials such as graphite, disordered carbon and modified carbon.

作者张宝郭华军李新海王志兴彭文杰

机构地区中南大学冶金科学与工程学院

出处《中南大学学报（自然科学版）》 EI CAS CSCD 北大核心 2007年第2期251-255,共5页 Journal of Central South University:Science and Technology

基金国家自然科学基金资助项目(50302016) 中国博士后基金资助项目(2005037698)

关键词锂离子电池负极碳石墨 lithium ion battery anode carbon graphite

分类号 TM912.9 [电气工程—电力电子与电力传动]

作者简介张宝（1971-1，男，江苏盱眙人，博士后，从事材料及电化学研究通讯作者：张宝，男，博士后；电话：0731—8836357;E-mail：zhangb@qianlong．com

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共引文献9

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同被引文献31

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引证文献2

1张宝,郭华军,李新海,王志兴,彭文杰.锂离子电池炭负极的结构与特性及其电化学性能[J].中南大学学报（自然科学版）,2007,38(3):454-460. 被引量：4
2赵洋,许广举,李铭迪,陈庆樟,王忠.柴油机EGR氛围下颗粒微观形貌与结构刚性的分析[J].汽车工程,2016,38(9):1052-1057. 被引量：4

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锂离子电池碳负极中边缘碳及表面碳原子含量的理论计算被引量：2

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锂离子电池碳负极中边缘碳及表面碳原子含量的理论计算 被引量：2

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锂离子电池碳负极中边缘碳及表面碳原子含量的理论计算被引量：2