Dynamics and spectroscopy of CH2OO excited electronic states

Jaroslaw Kalinowski; Elizabeth S. Foreman; Kara M. Kapnas; Craig Murray; Markku Räsänen; R. Benny Gerber

doi:10.1039/c6cp00807k

Dynamics and spectroscopy of CH₂OO excited electronic states

Jaroslaw Kalinowski^*, Elizabeth S. Foreman, Kara M. Kapnas, Craig Murray, Markku Räsänen, R. Benny Gerber

^*Corresponding author for this work

Institute of Chemistry

Research output: Contribution to journal › Article › peer-review

20 Scopus citations

Abstract

The excited states of the Criegee intermediate CH₂OO are studied in molecular dynamics simulations using directly potentials from multi-reference perturbation theory (MR-PT2). The photoexcitation of the species is simulated, and trajectories are propagated in time on the excited state. Some of the photoexcitation events lead to direct fragmentation of the molecule, but other trajectories describe at least several vibrations in the excited state, that may terminate by relaxation to the ground electronic state. Limits on the role of non-adiabatic contributions to the process are estimated by two different simulations, one that forces surface-hopping at potential crossings, and another that ignores surface hopping altogether. The effect of non-adiabatic transitions is found to be small. Spectroscopic implications and consequences for the interpretation of experimental results are discussed.

Original language	English
Pages (from-to)	10941-10946
Number of pages	6
Journal	Physical Chemistry Chemical Physics
Volume	18
Issue number	16
DOIs	https://doi.org/10.1039/c6cp00807k
State	Published - 28 Apr 2016

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abstract = "The excited states of the Criegee intermediate CH2OO are studied in molecular dynamics simulations using directly potentials from multi-reference perturbation theory (MR-PT2). The photoexcitation of the species is simulated, and trajectories are propagated in time on the excited state. Some of the photoexcitation events lead to direct fragmentation of the molecule, but other trajectories describe at least several vibrations in the excited state, that may terminate by relaxation to the ground electronic state. Limits on the role of non-adiabatic contributions to the process are estimated by two different simulations, one that forces surface-hopping at potential crossings, and another that ignores surface hopping altogether. The effect of non-adiabatic transitions is found to be small. Spectroscopic implications and consequences for the interpretation of experimental results are discussed.",

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AU - Kalinowski, Jaroslaw

AU - Foreman, Elizabeth S.

AU - Kapnas, Kara M.

AU - Murray, Craig

AU - Räsänen, Markku

AU - Benny Gerber, R.

PY - 2016/4/28

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AB - The excited states of the Criegee intermediate CH2OO are studied in molecular dynamics simulations using directly potentials from multi-reference perturbation theory (MR-PT2). The photoexcitation of the species is simulated, and trajectories are propagated in time on the excited state. Some of the photoexcitation events lead to direct fragmentation of the molecule, but other trajectories describe at least several vibrations in the excited state, that may terminate by relaxation to the ground electronic state. Limits on the role of non-adiabatic contributions to the process are estimated by two different simulations, one that forces surface-hopping at potential crossings, and another that ignores surface hopping altogether. The effect of non-adiabatic transitions is found to be small. Spectroscopic implications and consequences for the interpretation of experimental results are discussed.

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Dynamics and spectroscopy of CH₂OO excited electronic states

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