Issue 8, 2022

Degradation mechanism of 2-fluoropropene by Cl atoms: experimental and theoretical products distribution studies

Abstract

The gas-phase reaction products of 2-fluoropropene (2FP) with Cl atoms have been determined for the first time at 298 K and atmospheric pressure using a 1080 L quartz-glass photoreactor coupled with in situ FTIR spectroscopy to monitor reactants and products. Acetyl fluoride and formyl chloride were observed as the main products with yields of (106 ± 10)% and (100 ± 11)%, respectively. Electronic structure calculations of reactants, intermediates, products and transition states on a detailed mechanism of the reaction were performed by DFT procedures (BMK, M06, M062X/D3), as well as accurate composite methods on both the addition and abstraction reaction channels. From the joint experimental and theoretical studies, we concluded that the reaction occurs primarily via addition to the Cα carbon, with a smaller participation of the addition on the Cβ carbon, which is not produced directly from the separated reactants but from the CH3CFCH2Cl intermediate radical through a submerged transition state. The abstraction channel occurs at larger energies than the addition ones, and also presents a submerged transition state, with a lower barrier. No products arising from this channel are expected. The proposed mechanism explains also why formaldehyde, predicted as a product by former theoretical studies, is not found among the experimental products. The atmospheric implications of the reaction products are assessed.

Graphical abstract: Degradation mechanism of 2-fluoropropene by Cl atoms: experimental and theoretical products distribution studies

Supplementary files

Article information

Article type
Paper
Submitted
14 Jul 2021
Accepted
23 Dec 2021
First published
24 Dec 2021

Phys. Chem. Chem. Phys., 2022,24, 5094-5108

Degradation mechanism of 2-fluoropropene by Cl atoms: experimental and theoretical products distribution studies

C. B. Rivela, A. L. Cardona, M. B. Blanco, I. Barnes, M. Kieninger, O. N. Ventura and M. A. Teruel, Phys. Chem. Chem. Phys., 2022, 24, 5094 DOI: 10.1039/D1CP03214C

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