A Theoretical Perspective on the Actinic Photochemistry of 2-Hydroperoxypropanal

Emanuele Marsili; Antonio Prlj; Basile F E Curchod

doi:10.1021/acs.jpca.2c03783

A Theoretical Perspective on the Actinic Photochemistry of 2-Hydroperoxypropanal

Emanuele Marsili, Antonio Prlj, Basile F E Curchod^*

^*Corresponding author for this work

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Abstract

The photochemical reactions triggered by the sunlight absorption of transient volatile organic compounds in the troposphere are notoriously difficult to characterize experimentally due to the unstable and short-lived nature of these organic molecules. Some members of this family of compounds are likely to exhibit a rich photochemistry given the diversity of functional groups they can bear. Even more interesting is the photochemical fate of volatile organic compounds bearing more than one functional group that can absorb light─this is the case, for example, of α-hydroperoxycarbonyls, which are formed during the oxidation of isoprene. Experimental observables characterizing the photochemistry of these molecules like photoabsorption cross-sections or photolysis quantum yields are currently missing, and we propose here to leverage a recently developed computational protocol to predict in silico the photochemical fate of 2-hydroperoxypropanal (2-HPP) in the actinic region. We combine different levels of electronic structure methods─SCS-ADC(2) and XMS-CASPT2─with the nuclear ensemble approach and trajectory surface hopping to understand the mechanistic details of the possible nonradiative processes of 2-HPP. In particular, we predict the photoabsorption cross-section and the wavelength-dependent quantum yields for the observed photolytic pathways and combine them to determine in silico photolysis rate constants. The limitations of our protocol and possible future improvements are discussed.

Original language	English
Pages (from-to)	5420-5433
Number of pages	14
Journal	The journal of physical chemistry. A
Volume	126
Issue number	32
Early online date	28 Jul 2022
DOIs	https://doi.org/10.1021/acs.jpca.2c03783
Publication status	E-pub ahead of print - 28 Jul 2022

Bibliographical note

Funding Information:
This project has received funding from the European Research Council under the European Union’s Horizon 2020 research and innovation programme (Grant No. 803718, project SINDAM) and the EPSRC Grant EP/V026690/1. This article is based upon work from European Cooperation in Science and Technology (COST) Action CA18212─Molecular Dynamics in the GAS phase, supported by COST, and made use of the facilities of the Hamilton HPC Service of Durham University. a

Publisher Copyright:
© 2022 The Authors. Published by American Chemical Society.

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title = "A Theoretical Perspective on the Actinic Photochemistry of 2-Hydroperoxypropanal",

abstract = "The photochemical reactions triggered by the sunlight absorption of transient volatile organic compounds in the troposphere are notoriously difficult to characterize experimentally due to the unstable and short-lived nature of these organic molecules. Some members of this family of compounds are likely to exhibit a rich photochemistry given the diversity of functional groups they can bear. Even more interesting is the photochemical fate of volatile organic compounds bearing more than one functional group that can absorb light─this is the case, for example, of α-hydroperoxycarbonyls, which are formed during the oxidation of isoprene. Experimental observables characterizing the photochemistry of these molecules like photoabsorption cross-sections or photolysis quantum yields are currently missing, and we propose here to leverage a recently developed computational protocol to predict in silico the photochemical fate of 2-hydroperoxypropanal (2-HPP) in the actinic region. We combine different levels of electronic structure methods─SCS-ADC(2) and XMS-CASPT2─with the nuclear ensemble approach and trajectory surface hopping to understand the mechanistic details of the possible nonradiative processes of 2-HPP. In particular, we predict the photoabsorption cross-section and the wavelength-dependent quantum yields for the observed photolytic pathways and combine them to determine in silico photolysis rate constants. The limitations of our protocol and possible future improvements are discussed.",

author = "Emanuele Marsili and Antonio Prlj and Curchod, {Basile F E}",

note = "Funding Information: This project has received funding from the European Research Council under the European Union{\textquoteright}s Horizon 2020 research and innovation programme (Grant No. 803718, project SINDAM) and the EPSRC Grant EP/V026690/1. This article is based upon work from European Cooperation in Science and Technology (COST) Action CA18212─Molecular Dynamics in the GAS phase, supported by COST, and made use of the facilities of the Hamilton HPC Service of Durham University. a Publisher Copyright: {\textcopyright} 2022 The Authors. Published by American Chemical Society.",

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N1 - Funding Information: This project has received funding from the European Research Council under the European Union’s Horizon 2020 research and innovation programme (Grant No. 803718, project SINDAM) and the EPSRC Grant EP/V026690/1. This article is based upon work from European Cooperation in Science and Technology (COST) Action CA18212─Molecular Dynamics in the GAS phase, supported by COST, and made use of the facilities of the Hamilton HPC Service of Durham University. a Publisher Copyright: © 2022 The Authors. Published by American Chemical Society.

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N2 - The photochemical reactions triggered by the sunlight absorption of transient volatile organic compounds in the troposphere are notoriously difficult to characterize experimentally due to the unstable and short-lived nature of these organic molecules. Some members of this family of compounds are likely to exhibit a rich photochemistry given the diversity of functional groups they can bear. Even more interesting is the photochemical fate of volatile organic compounds bearing more than one functional group that can absorb light─this is the case, for example, of α-hydroperoxycarbonyls, which are formed during the oxidation of isoprene. Experimental observables characterizing the photochemistry of these molecules like photoabsorption cross-sections or photolysis quantum yields are currently missing, and we propose here to leverage a recently developed computational protocol to predict in silico the photochemical fate of 2-hydroperoxypropanal (2-HPP) in the actinic region. We combine different levels of electronic structure methods─SCS-ADC(2) and XMS-CASPT2─with the nuclear ensemble approach and trajectory surface hopping to understand the mechanistic details of the possible nonradiative processes of 2-HPP. In particular, we predict the photoabsorption cross-section and the wavelength-dependent quantum yields for the observed photolytic pathways and combine them to determine in silico photolysis rate constants. The limitations of our protocol and possible future improvements are discussed.

AB - The photochemical reactions triggered by the sunlight absorption of transient volatile organic compounds in the troposphere are notoriously difficult to characterize experimentally due to the unstable and short-lived nature of these organic molecules. Some members of this family of compounds are likely to exhibit a rich photochemistry given the diversity of functional groups they can bear. Even more interesting is the photochemical fate of volatile organic compounds bearing more than one functional group that can absorb light─this is the case, for example, of α-hydroperoxycarbonyls, which are formed during the oxidation of isoprene. Experimental observables characterizing the photochemistry of these molecules like photoabsorption cross-sections or photolysis quantum yields are currently missing, and we propose here to leverage a recently developed computational protocol to predict in silico the photochemical fate of 2-hydroperoxypropanal (2-HPP) in the actinic region. We combine different levels of electronic structure methods─SCS-ADC(2) and XMS-CASPT2─with the nuclear ensemble approach and trajectory surface hopping to understand the mechanistic details of the possible nonradiative processes of 2-HPP. In particular, we predict the photoabsorption cross-section and the wavelength-dependent quantum yields for the observed photolytic pathways and combine them to determine in silico photolysis rate constants. The limitations of our protocol and possible future improvements are discussed.

U2 - 10.1021/acs.jpca.2c03783

DO - 10.1021/acs.jpca.2c03783

M3 - Article (Academic Journal)

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SN - 1089-5639

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JO - The journal of physical chemistry. A

JF - The journal of physical chemistry. A

IS - 32

ER -

A Theoretical Perspective on the Actinic Photochemistry of 2-Hydroperoxypropanal

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