Electron and nuclear dynamics following molecular ionisation : computational methods and applications

The emergence of attosecond techniques has opened up the possibility to experimentally probe changes in the electron distribution, that until now have been treated as instantaneous. Photoionisation of molecules with attosecond (broad bandwidth) pulses leads to a non-stationary electronic wave packet...

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Main Author: Vacher, Morgane
Other Authors: Bearpark, Michael J.
Published: Imperial College London 2016
Subjects:
540
Online Access:https://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.733087
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spelling ndltd-bl.uk-oai-ethos.bl.uk-7330872019-03-05T15:33:06ZElectron and nuclear dynamics following molecular ionisation : computational methods and applicationsVacher, MorganeBearpark, Michael J.2016The emergence of attosecond techniques has opened up the possibility to experimentally probe changes in the electron distribution, that until now have been treated as instantaneous. Photoionisation of molecules with attosecond (broad bandwidth) pulses leads to a non-stationary electronic wave packet. The current state-of-the-art for ab initio theory treats molecular electron dynamics as a purely electronic process, at a single fixed nuclear geometry. The present thesis is concerned with fundamental questions about the physics of non-stationary electronic wave packets and the coupling of this motion to that of the nuclei. To simulate coupled electron and nuclear dynamics, we use the “on-the-fly” mixed quantum-classical Ehrenfest method and the quantum mechanical DD-vMCG method. The results obtained with the two methods are compared. We choose to study electron and nuclear dynamics upon ionisation of benzene, toluene and para- xylene as examples because vertical ionisation takes place at geometries near the conical intersections between ground and first excited states of their cations, leading to a potentially strong coupling between the electronic and nuclear coordinates. One aim is to investigate electron dynamics and how it is affected by the nuclei. We show significant effects of the nuclear motion after a few femtoseconds within the Ehrenfest approximation. We also show how the inherent spatial delocalisation of the nuclei leads to very fast dephasing of electron dynamics, using a Wigner distribution. The DD-vMCG simulations confirm the very fast dephasing of electron dynamics in the molecules studied. A complementary aspect of the dynamics upon ionisation is the nuclear motion induced by an electronic wave packet. We show how the averaged initial nuclear motion (direction and velocity) is controlled by the composition of the electronic wave packet, as predicted by the Ehrenfest method. The DD-vMCG method provides the details of the nuclear dynamics on each electronic state.540Imperial College Londonhttps://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.733087http://hdl.handle.net/10044/1/56110Electronic Thesis or Dissertation
collection NDLTD
sources NDLTD
topic 540
spellingShingle 540
Vacher, Morgane
Electron and nuclear dynamics following molecular ionisation : computational methods and applications
description The emergence of attosecond techniques has opened up the possibility to experimentally probe changes in the electron distribution, that until now have been treated as instantaneous. Photoionisation of molecules with attosecond (broad bandwidth) pulses leads to a non-stationary electronic wave packet. The current state-of-the-art for ab initio theory treats molecular electron dynamics as a purely electronic process, at a single fixed nuclear geometry. The present thesis is concerned with fundamental questions about the physics of non-stationary electronic wave packets and the coupling of this motion to that of the nuclei. To simulate coupled electron and nuclear dynamics, we use the “on-the-fly” mixed quantum-classical Ehrenfest method and the quantum mechanical DD-vMCG method. The results obtained with the two methods are compared. We choose to study electron and nuclear dynamics upon ionisation of benzene, toluene and para- xylene as examples because vertical ionisation takes place at geometries near the conical intersections between ground and first excited states of their cations, leading to a potentially strong coupling between the electronic and nuclear coordinates. One aim is to investigate electron dynamics and how it is affected by the nuclei. We show significant effects of the nuclear motion after a few femtoseconds within the Ehrenfest approximation. We also show how the inherent spatial delocalisation of the nuclei leads to very fast dephasing of electron dynamics, using a Wigner distribution. The DD-vMCG simulations confirm the very fast dephasing of electron dynamics in the molecules studied. A complementary aspect of the dynamics upon ionisation is the nuclear motion induced by an electronic wave packet. We show how the averaged initial nuclear motion (direction and velocity) is controlled by the composition of the electronic wave packet, as predicted by the Ehrenfest method. The DD-vMCG method provides the details of the nuclear dynamics on each electronic state.
author2 Bearpark, Michael J.
author_facet Bearpark, Michael J.
Vacher, Morgane
author Vacher, Morgane
author_sort Vacher, Morgane
title Electron and nuclear dynamics following molecular ionisation : computational methods and applications
title_short Electron and nuclear dynamics following molecular ionisation : computational methods and applications
title_full Electron and nuclear dynamics following molecular ionisation : computational methods and applications
title_fullStr Electron and nuclear dynamics following molecular ionisation : computational methods and applications
title_full_unstemmed Electron and nuclear dynamics following molecular ionisation : computational methods and applications
title_sort electron and nuclear dynamics following molecular ionisation : computational methods and applications
publisher Imperial College London
publishDate 2016
url https://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.733087
work_keys_str_mv AT vachermorgane electronandnucleardynamicsfollowingmolecularionisationcomputationalmethodsandapplications
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