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Gas-Phase Phenyl Radical + O 2 Reacts via a Submerged Transition State.

Oisin J ShielsSamuel J P MarltonBerwyck L J PoadStephen J BlanksbyGabriel da SilvaAdam J Trevitt
Published in: The journal of physical chemistry. A (2024)
In the gas-phase chemistry of the atmosphere and automotive fuel combustion, peroxyl radical intermediates are formed following O 2 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 O 2 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 O 2 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.
Keyphrases
  • density functional theory
  • risk assessment
  • particulate matter
  • mass spectrometry
  • air pollution
  • molecular docking