Ab Initio Study of the Potential Energy Surface and Product Branching Ratios for the Reaction of O(D-1) With CH3CH2Br
Tian, Z; Song, C; Li, Q
| HERO ID | 4248152 |
|---|---|
| In Press | No |
| Year | 2011 |
| Title | Ab Initio Study of the Potential Energy Surface and Product Branching Ratios for the Reaction of O(D-1) With CH3CH2Br |
| Authors | Tian, Z; Song, C; Li, Q |
| Journal | International Journal of Quantum Chemistry |
| Volume | 111 |
| Issue | 3 |
| Page Numbers | 631-643 |
| Abstract | The potential energy surface of O(D-1) + CH3CH2Br reaction has been studied using QCISD(T)/6-311++G(d,p)//MP2/6-311G(d,p) method. The calculations reveal an insertion-elimination reaction mechanism of the title reaction. The insertion process has two possibilities: one is the O(D-1) inserting into C-Br bond of CH3CH2Br producing one energy-rich intermediate CH3CH2OBr and another is the O(D-1) inserting into one of the C-H bonds of CH3CH2Br producing two energy-rich intermediates, IM1 and IM2. The three intermediates subsequently decompose to various products. The calculations of the branching ratios of various products formed though the three intermediates have been carried out using RRKM theory at the collision energies of 0, 5, 10, 15, 20, 25, and 30 kcal/mol. CH3CH2O + Br are the main decomposition products of CH3CH2OBr. CH3COH + HBr and CH2CHOH + HBr are the main decomposition products for IM1; CH2CHOH + HBr are the main decomposition products for IM2. As IM1 is more stable and more likely to form than CH3CH2OBr and IM2, CH3COH + HBr and CH2CHOH + HBr are probably the main products of the O(D-1) + CH3CH2Br reaction. Our computational results can give insight into reaction mechanism and provide probable explanations for future experiments. (C) 2009 Wiley Periodicals, Inc. Int J Quantum Chem 111: 631-643, 2011 |
| Doi | 10.1002/qua.22444 |
| Wosid | WOS:000285311800008 |
| Is Certified Translation | No |
| Dupe Override | No |
| Is Public | Yes |
| Keyword | CH3CH2Br; rate constant; branching ratio; decomposition channel; potential energy surface |