A Theoretical and Computational Analysis of the Methyl-Vinyl
+ O<sub>2</sub> Reaction and Its Effects on Propene Combustion
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Abstract
A detailed
analysis of the reaction of CH<sub>3</sub>CCH<sub>2</sub> and CH<sub>3</sub>CHCH with molecular oxygen is presented. The C<sub>3</sub>H<sub>5</sub>O<sub>2</sub> potential energy surface was characterized
using a combination of electronic structure methods. The majority
of the stationary points on the PES was determined at the CCSD(T)-F12a/cc-pVTZ-F12//B2PLYPD3/cc-pVTZ
level of theory, with the remaining transition states computed using
multireference methods. Microcanonical rate theory and the master
equation are used to determine the temperature- and pressure-dependent
rate coefficients for each reaction channel. The main product channels
are CH<sub>2</sub>O + CH<sub>3</sub>CO for CH<sub>3</sub>CCH<sub>2</sub> and CH3CHO + CHO for CH<sub>3</sub>CHCH. The rate constants for
these two reactions at 1 atm are <i>k</i> = 9.03 ×
10<sup>22</sup> × <i>T</i><sup>–3.21</sup> ×
exp<sup>–2162/<i>T</i></sup> and 1.50 × 10<sup>19</sup> × <i>T</i><sup>–2.10</sup> ×
exp<sup>–1260/<i>T</i></sup> cm<sup>–3</sup> mol<sup>–1</sup> s<sup>–1</sup>, respectively. In
contrast to C<sub>2</sub>H<sub>3</sub> + O<sub>2</sub>, the methyl-vinyl
+ O<sub>2</sub> reactions remain chain propagating, even at high temperatures.
The new rate coefficients were implemented in a detailed mechanism
taken from the literature. These changes have a modest effect on the
ignition delay time and laminar flame speeds for propene combustion