Theoretical study of the reaction mechanism and kinetics of the OH + trimethyl orthoformate ((CH3O)3CH)+ O2 reaction

Publication date: Available online 21 May 2019Source: Computational and Theoretical ChemistryAuthor(s): Benni Du, Weichao ZhangAbstractThe profiles of potential energy surface (PES) of Trimethyl orthoformate (TMOF) with OH radicals under atmospheric conditions have been studied by performing M06-2X-GD3/6-311++G(d,p) approach for geometry optimization and ab initio method QCISD (T)/6-311++G(d,p) for energy calculations. The reaction of the OH radicals with TMOF in the presence of O2 is found to form mainly OH radicals, 2, 2-dimethoxy-1, 3-dioxetane, dimethyl carbonate [(CH3O)2CO] and HC(O)H. Regeneration of OH radicals for the TMOF+OH+O2 reaction is verified in the present calculations, which is consistent with the experimental observations. Based on the PES of the TMOF+OH reaction, temperature-dependent rate coefficients and branching ratios at 298−1500 K are determined using the conventional transition state theory. At 298 K , the calculated individual rate coefficients for H-abstraction from the −CH− site and the CH3O– site of TMOF are 3.90×10-12 and 1.58×10-12 cm3 molecule−1 s−1, respectively. It is found that ∼71% of the TMOF+OH reaction takes place through the −CH− site H-abstraction and ∼29% of the TMOF+OH reaction belongs to the CH3O– site H-abstraction. The overall rate coefficient displays opposite temperature dependencies at low and high temperatures, viz., negative at low temperatures and positive at high temperatures. In the temperature ran...
Source: Computational and Theoretical Chemistry - Category: Chemistry Source Type: research
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