Thermodynamic analysis and dynamics simulation on reaction of Al_2O and AlCl_2 with carbon under vacuum 被引量：1

Thermodynamic analysis and dynamics simulation on reaction of Al_2O and AlCl_2 with carbon under vacuum

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摘要 The feasibility study of the AlCl(g) generated by Al_2O-AlCl_2-C system under vacuum was carried out by thermodynamic analysis and CASTEP package of the Material Studio program which was based on density functional theory(DFT) formalism. Thermodynamic calculations indicate that Al Cl and CO molecules can be formed under conditions of temperature 1760 K and the pressure of 60 Pa. The interaction of Al_2O and AlCl_2 with C shows that the chemical adsorption of Al_2O and AlCl_2 does take place on C(001) crystal plane, and at the same time, new chemical bond is formed between Al atom in Al_2O and Cl atoms from one of the Al—Cl bonds in AlCl_2. The results, after 1.25 ps dynamics simulation, indicate that adsorbed Al Cl molecules are generated and CO molecule will be formed in this system, and they will escape from C(001) surface after a longer period of dynamic simulation time. It means that the reaction of Al_2O and AlCl_2 with C can be carried out under given constraint condition. The feasibility study of the AlCl（g） generated by Al_2O-AlCl_2-C system under vacuum was carried out by thermodynamic analysis and CASTEP package of the Material Studio program which was based on density functional theory（DFT） formalism. Thermodynamic calculations indicate that Al Cl and CO molecules can be formed under conditions of temperature 1760 K and the pressure of 60 Pa. The interaction of Al_2O and AlCl_2 with C shows that the chemical adsorption of Al_2O and AlCl_2 does take place on C（001） crystal plane, and at the same time, new chemical bond is formed between Al atom in Al_2O and Cl atoms from one of the Al-Cl bonds in AlCl_2. The results, after 1.25 ps dynamics simulation, indicate that adsorbed Al Cl molecules are generated and CO molecule will be formed in this system, and they will escape from C（001） surface after a longer period of dynamic simulation time. It means that the reaction of Al_2O and AlCl_2 with C can be carried out under given constraint condition.

作者卢勇周岳珍陈秀敏李紫勇郁青春刘大春杨斌徐宝强

机构地区 National Engineering Laboratory for Vacuum Metallurgy(Kunming University of Science and Technology) Yunnan Provincial Key Laboratory of Nonferrous Vacuum Metallurgy

出处《Journal of Central South University》 SCIE EI CAS CSCD 2016年第2期286-292,共7页 中南大学学报（英文版）

基金 Projects(51104078,51264023)supported by the National Natural Science Foundation of China Project(2010CD022)supported by Yunnan Province Applied Basic Research Fund,China Project(IRT1250)supported by the Program for Innovative Research Team in University of Ministry of Education of China Project(U1202271)supported by the National Natural Science Foundation of China-Yunnan United Fund Project(KKZ3201252020)supported by Kunming University of Science and Technology for Talent Training,China

关键词 Ab initio molecular dynamics carbothermic-chlorination （AlCl2） reaction THERMODYNAMICS INTERACTION Al2O 热力学分析动力学仿真反应真空密度泛函理论 CO分子碳化学吸附

分类号 TQ133.1 [化学工程—无机化工] O642 [理学—物理化学]

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