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Gas-Phase Peroxyl Radical Recombination Reactions: A Computational Study of Formation and Decomposition of Tetroxides

Vili-Taneli Salo, Rashid R. Valiev, Susi Lehtola, Theo Kurtén

2022The Journal of Physical Chemistry A36 citationsDOIOpen Access PDF

Abstract

) and a triplet pair of alkoxyl radicals (RO•). We demonstrate this mechanism for several atmospherically relevant primary and secondary peroxyl radicals. The potential energy surface corresponds to an overall singlet state. The subsequent reaction channels of the alkoxyl radicals include, but are not limited to, their dimerization into ROOR'. Our work considers the multiconfigurational character of the tetroxides and the intermediate phases of the reaction, leading to reliable mechanistic insights for the formation and decomposition of the tetroxides. Despite substantial uncertainties in the computed energetics, our results demonstrate that the barrier heights along the reaction path are invariably small for these systems. This suggests that the reaction mechanism, previously validated at a multireference level only for methyl peroxyl radicals, is a plausible pathway for the formation of aerosol-relevant larger peroxides in the atmosphere.

Topics & Concepts

RadicalChemistryPhotochemistryAlkoxy groupDecompositionSinglet stateReaction mechanismComputational chemistryCatalysisOrganic chemistryAlkylExcited statePhysicsNuclear physicsAtmospheric chemistry and aerosolsAtmospheric Ozone and ClimateAir Quality and Health Impacts