Kinetic Modeling of the Gas Phase Decomposition of Germane by Computational Chemistry Techniques

M. Hierlemann, H. Simka, K. Jensen, M. Utz
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引用次数: 3

Abstract

Very limited experimental data are available on thermal decomposition of germane in the gas phase. Recent developments in theoretical quantum chemistry techniques such as ab initio Hartree-Fock and density functional methods have made accurate determination of molecular properties possible. Systematic development of a detailed gas-phase decomposition mechanism for germane using ab initio molecular orbital calculations is described in this work. A decomposition pathway for germane and higher germanes is proposed and the relevant reaction rates are calculated using transition state theory combined with unimolecular and chemical activation treatments. The decomposition model is implemented into a realistic thermal-fluid simulation.
计算化学技术对日耳曼气相分解的动力学模拟
关于锗在气相中热分解的实验数据非常有限。理论量子化学技术的最新发展,如从头算Hartree-Fock和密度泛函方法,使分子性质的精确测定成为可能。系统开发了详细的气相分解机制,使用从头算分子轨道计算描述了这项工作。提出了日耳曼和高级日耳曼的分解途径,并利用过渡态理论结合单分子和化学活化处理计算了相应的反应速率。将分解模型应用到实际的热流体模拟中。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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