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Gas-Phase Phenyl Radical + O2 Reacts via a Submerged Transition State

journal contribution
posted on 2024-11-17, 13:07 authored by Oisin J Shiels, Samuel JP Marlton, Berwyck LJ Poad, Stephen J Blanksby, Gabriel da Silva, Adam J Trevitt
In the gas-phase chemistry of the atmosphere and automotive fuel combustion, peroxyl radical intermediates are formed following O2 addition to carbon-centered radicals which then initiate a complex network of radical reactions that govern the oxidative processing of hydrocarbons. The rapid association of the phenyl radical-a fundamental radical related to benzene-with O2 has hitherto been modeled as a barrierless process, a common assumption for peroxyl radical formation. Here, we provide an alternate explanation for the kinetics of this reaction by deploying double-hybrid density functional theory (DFT), at the DSD-PBEP86-D3(BJ)/aug-cc-pVTZ level of theory, and locate a submerged adiabatic transition state connected to a prereaction complex along the reaction entrance pathway. Using this potential energy scheme, experimental rate coefficients k(T) for the addition of O2 to the phenyl radical are accurately reproduced within a microcanonical kinetic model. This work highlights that purportedly barrierless radical oxidation reactions may instead be modeled using stationary points, which in turn provides insight into pressure and temperature dependence.

Funding

Australian Research Council (DP170101596)

History

Journal title

Journal of Physical Chemistry A

Volume

128

Issue

2

Pagination

413-419

Language

English

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