Fikri Mustapha, Makeich Alexander, Rollmann Georg, Schulz Christof, Entel Peter
IVG, Theoretische Physik, and CeNIDE, Center for Nanointegration, Universität Duisburg-Essen, Duisburg, Germany.
J Phys Chem A. 2008 Jul 17;112(28):6330-7. doi: 10.1021/jp801516y. Epub 2008 Jun 25.
The thermal decomposition of Ga(CH3)3 has been studied both experimentally in shock-heated gases and theoretically within an ab-initio framework. Experiments for pressures ranging from 0.3 to 4 bar were performed in a shock tube equipped with atomic resonance absorption spectroscopy (ARAS) for Ga atoms at 403.3 nm. Time-resolved measurements of Ga atom concentrations were conducted behind incident waves as well as behind reflected shock waves at temperatures between 1210 and 1630 K. The temporal variation in Ga-atom concentration was described by a reaction mechanism involving the successive abstraction of methyl radicals from Ga(CH3)3 (R1), Ga(CH3)2 (R2), and GaCH3 (R3), respectively, where the last reaction is the rate-limiting step leading to Ga-atom formation. The rate constant of this reaction (R3) was deduced from a simulation of the measured Ga-atom concentration profiles using thermochemical data from ab-initio calculations for the reactions R1 and R2 as input. The Rice-Ramsperger-Kassel-Marcus (RRKM) method including variational transition state theory was applied for reaction R3 assuming a loose transition state. Structural parameters and vibrational frequencies of the reactant and transition state required for the RRKM calculations were obtained from first-principles simulations. The energy barrier E3(0) of reaction R3, which is the most sensitive parameter in the calculation, was adjusted until the RRKM rate constant matched the experimental one and was found to be E(0) = 288 kJ/mol. This value is in a good agreement with the corresponding ab-initio value of 266 kJ/mol. The rate constant of reaction R3 was found to be k 3/(cm(3) mol(-1)s(-1)) = 2.34 x 10(11) exp[-23330(K/ T)].
已在冲击加热气体中通过实验研究了三甲基镓(Ga(CH₃)₃)的热分解,并在从头算框架内进行了理论研究。在配备有用于403.3 nm处镓原子的原子共振吸收光谱(ARAS)的激波管中,对压力范围为0.3至4 bar进行了实验。在1210至1630 K的温度下,在入射波后以及反射激波后进行了镓原子浓度的时间分辨测量。镓原子浓度的时间变化通过一种反应机制来描述,该机制分别涉及从Ga(CH₃)₃(R1)、Ga(CH₃)₂(R2)和GaCH₃(R3)依次提取甲基自由基,其中最后一个反应是导致镓原子形成的限速步骤。该反应(R3)的速率常数是通过使用反应R1和R2的从头算计算得到的热化学数据作为输入,对测量的镓原子浓度分布进行模拟推导出来的。假设过渡态较松散,对反应R3应用了包括变分过渡态理论的赖斯 - 拉姆斯佩格 - 卡塞尔 - 马库斯(RRKM)方法。RRKM计算所需的反应物和过渡态的结构参数及振动频率是从第一性原理模拟中获得的。反应R3的能垒E3(0)是计算中最敏感的参数,对其进行调整直到RRKM速率常数与实验值匹配,发现E(0) = 288 kJ/mol。该值与相应的从头算值266 kJ/mol吻合良好。发现反应R3的速率常数为k 3/(cm³ mol⁻¹ s⁻¹) = 2.34 x 10¹¹ exp[-23330(K/T)] 。