Synergistic catalytic effect of light rare earth element and other additives on the degree of graphitization and properties of graphite
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- 作者:Rongyan Wang ; Guimin Lu ; Haizheng Zhuang ; Jianguo Yu
- 刊名:Journal of Materials Science
- 出版年:2017
- 出版时间:January 2017
- 年:2017
- 卷:52
- 期:2
- 页码:663-673
- 全文大小:1,974 KB
- 刊物类别:Chemistry and Materials Science
- 刊物主题:Chemistry
Materials Science
Characterization and Evaluation Materials
Polymer Sciences
Continuum Mechanics and Mechanics of Materials
Crystallography
Mechanics - 出版者:Springer Netherlands
- ISSN:1573-4803
- 卷排序:52
文摘
Metal additives usually have a catalytic effect on non-graphitic carbon materials. However, graphitic carbon materials are difficult to catalyze owing to carbon atoms whose neighbors are ordered regions and less cross-linked. Artificial graphite is generally prepared from coke and pitch, both of which are graphitic carbon. Therefore, efficient catalysts for graphitic carbon materials are important for industrial technology. The effect of light rare earth elements (La, Ce, and Pr) and other additives (Ti, Ni, and B) as co-catalysts in artificial graphite development was investigated. Compared with the single catalysts, the combinatorial catalysts more significantly improved the degree of graphitization in the carbon materials, indicating synergistic catalytic effects. Both dissolution–precipitation and formation–decomposition of carbide were involved in the synergistic catalytic mechanisms. In the combinatorial catalysts systems, the light rare earth element would accelerate the graphitization process of carbon materials by widening the range of the catalytic temperature, accelerating the speed of oversaturation of dissolution, or generating a new carbide phase with the other catalyst. This would promote formation of the more-ordered graphitic structure at relatively low temperature. For instance, to attain the same degree of graphitization and better crystalline sizes at the same residence time, the carbon materials with combinatorial catalysts can be heat treated at temperatures 400 °C lower than without catalysts, and the electrical and mechanical properties are enhanced.