Quantum dynamics study of the competing ultrafast intersystem crossing and internal conversion in the “channel 3” region of benzene
Quantum dynamics study of the competing ultrafast intersystem crossing and internal conversion in the “channel 3” region of benzene
Time-resolved photoelectron spectroscopy can obtain detailed information about the dynamics of a chemical process on the femtosecond timescale. The resulting signal from such detailed experiments is often difficult to analyze and therefore theoretical calculations are important in providing support. In this paper we continue our work on the competing pathways in the photophysics and photochemistry of benzene after excitation into the “channel 3” region [R. S. Minns, D. S. N. Parker, T. J. Penfold, G. A. Worth, and H. H. Fielding, Phys. Chem. Chem. Phys. 12, 15607 (2010)] with details of the calculations shown previously, building on a vibronic coupling Hamiltonian [T. J. Penfold and G. A. Worth, J. Chem. Phys. 131, 064303 (2009)] to include the triplet manifold. New experimental data are also presented suggesting that an oscillatory signal is due to a hot band excitation. The experiments show that signals are obtained from three regions of the potential surfaces, three open channels, which are assigned with the help of simulations showing that following excitation into vibrationally excited-states of S1 the wavepacket not only crosses through the prefulvenoid conical intersection back to the singlet ground state, but also undergoes ultrafast intersystem crossing to low lying triplet states. The model is, however, not detailed enough to capture the full details of the oscillatory signal due to the hot band.
24310-24311
Penfold, T. J.
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Spesyvtsev, R
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Kirkby, O. M.
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Minns, R. S.
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Parker, D. S. N.
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Fiedling, H. H.
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Worth, G. A,
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28 November 2012
Penfold, T. J.
e13f9bf0-4527-4fd9-9684-3676baaadaee
Spesyvtsev, R
559266dc-8259-4b68-9434-418492b337e9
Kirkby, O. M.
1974b7c5-eb8b-43ee-87c6-1620e11b7a05
Minns, R. S.
85280db4-c5a6-4a4c-82fe-75693c6a6045
Parker, D. S. N.
0899bea7-2078-4551-9a17-e09690cb16e7
Fiedling, H. H.
9ffc66cb-fa46-4511-9cd4-83fe25fe2348
Worth, G. A,
72232e75-3702-4c51-a885-3f2e492dc1bc
Penfold, T. J., Spesyvtsev, R, Kirkby, O. M., Minns, R. S., Parker, D. S. N., Fiedling, H. H. and Worth, G. A,
(2012)
Quantum dynamics study of the competing ultrafast intersystem crossing and internal conversion in the “channel 3” region of benzene.
The Journal of Chemical Physics, 137, .
(doi:10.1063/1.4767054).
Abstract
Time-resolved photoelectron spectroscopy can obtain detailed information about the dynamics of a chemical process on the femtosecond timescale. The resulting signal from such detailed experiments is often difficult to analyze and therefore theoretical calculations are important in providing support. In this paper we continue our work on the competing pathways in the photophysics and photochemistry of benzene after excitation into the “channel 3” region [R. S. Minns, D. S. N. Parker, T. J. Penfold, G. A. Worth, and H. H. Fielding, Phys. Chem. Chem. Phys. 12, 15607 (2010)] with details of the calculations shown previously, building on a vibronic coupling Hamiltonian [T. J. Penfold and G. A. Worth, J. Chem. Phys. 131, 064303 (2009)] to include the triplet manifold. New experimental data are also presented suggesting that an oscillatory signal is due to a hot band excitation. The experiments show that signals are obtained from three regions of the potential surfaces, three open channels, which are assigned with the help of simulations showing that following excitation into vibrationally excited-states of S1 the wavepacket not only crosses through the prefulvenoid conical intersection back to the singlet ground state, but also undergoes ultrafast intersystem crossing to low lying triplet states. The model is, however, not detailed enough to capture the full details of the oscillatory signal due to the hot band.
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Published date: 28 November 2012
Organisations:
Computational Systems Chemistry
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Local EPrints ID: 345733
URI: http://eprints.soton.ac.uk/id/eprint/345733
ISSN: 0021-9606
PURE UUID: ab7f5ce8-c23e-42b8-ad09-121971dad89a
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Date deposited: 29 Nov 2012 14:15
Last modified: 15 Mar 2024 03:40
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Contributors
Author:
T. J. Penfold
Author:
R Spesyvtsev
Author:
O. M. Kirkby
Author:
D. S. N. Parker
Author:
H. H. Fiedling
Author:
G. A, Worth
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