Revealing Ultrafast Population Transfer between Nearly Degenerate Electronic States

Pascal Heim; Sebastian Mai; Bernhard Thaler; Stefan Cesnik; Davide Avagliano; Dimitra Bella-Veliduo; Wolfgang E. Ernst; Leticia González; Markus Koch

doi:10.1021/acs.jpclett.9b03462

Revealing Ultrafast Population Transfer between Nearly Degenerate Electronic States

Pascal Heim, Sebastian Mai, Bernhard Thaler, Stefan Cesnik, Davide Avagliano, Dimitra Bella-Veliduo, Wolfgang E. Ernst, Leticia González^*, Markus Koch

^*Corresponding author for this work

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

Abstract

The response of a molecule to photoexcitation is governed by the coupling of its electronic states. However, if the energetic spacing between the electronically excited states at the Franck-Condon window becomes sufficiently small, it is infeasible to selectively excite and monitor individual states with conventional time-resolved spectroscopy, preventing insight into the energy transfer and relaxation dynamics of the molecule. Here, we demonstrate how the combination of time-resolved spectroscopy and extensive surface hopping dynamics simulations with a global fit approach on individually excited ensembles overcomes this limitation and resolves the dynamics in the n3p Rydberg states in acetone. Photoelectron transients of the three closely spaced states n3p _x, n3p _y, and n3p _z are used to validate the theoretical results, which in turn allow retrieving a comprehensive kinetic model describing the mutual interactions of these states for the first time.

Original language	English
Pages (from-to)	1443-1449
Number of pages	7
Journal	The Journal of Physical Chemistry Letters
Volume	11
Issue number	4
DOIs	https://doi.org/10.1021/acs.jpclett.9b03462
Publication status	Published - 20 Feb 2020

ASJC Scopus subject areas

Materials Science(all)
Physical and Theoretical Chemistry

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Advanced Materials Science

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NAWI Graz

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10.1021/acs.jpclett.9b03462Licence: CC BY 4.0

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title = "Revealing Ultrafast Population Transfer between Nearly Degenerate Electronic States",

abstract = "The response of a molecule to photoexcitation is governed by the coupling of its electronic states. However, if the energetic spacing between the electronically excited states at the Franck-Condon window becomes sufficiently small, it is infeasible to selectively excite and monitor individual states with conventional time-resolved spectroscopy, preventing insight into the energy transfer and relaxation dynamics of the molecule. Here, we demonstrate how the combination of time-resolved spectroscopy and extensive surface hopping dynamics simulations with a global fit approach on individually excited ensembles overcomes this limitation and resolves the dynamics in the n3p Rydberg states in acetone. Photoelectron transients of the three closely spaced states n3p x, n3p y, and n3p z are used to validate the theoretical results, which in turn allow retrieving a comprehensive kinetic model describing the mutual interactions of these states for the first time. ",

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AU - Heim, Pascal

AU - Mai, Sebastian

AU - Thaler, Bernhard

AU - Cesnik, Stefan

AU - Avagliano, Davide

AU - Bella-Veliduo, Dimitra

AU - Ernst, Wolfgang E.

AU - González, Leticia

AU - Koch, Markus

PY - 2020/2/20

Y1 - 2020/2/20

N2 - The response of a molecule to photoexcitation is governed by the coupling of its electronic states. However, if the energetic spacing between the electronically excited states at the Franck-Condon window becomes sufficiently small, it is infeasible to selectively excite and monitor individual states with conventional time-resolved spectroscopy, preventing insight into the energy transfer and relaxation dynamics of the molecule. Here, we demonstrate how the combination of time-resolved spectroscopy and extensive surface hopping dynamics simulations with a global fit approach on individually excited ensembles overcomes this limitation and resolves the dynamics in the n3p Rydberg states in acetone. Photoelectron transients of the three closely spaced states n3p x, n3p y, and n3p z are used to validate the theoretical results, which in turn allow retrieving a comprehensive kinetic model describing the mutual interactions of these states for the first time.

AB - The response of a molecule to photoexcitation is governed by the coupling of its electronic states. However, if the energetic spacing between the electronically excited states at the Franck-Condon window becomes sufficiently small, it is infeasible to selectively excite and monitor individual states with conventional time-resolved spectroscopy, preventing insight into the energy transfer and relaxation dynamics of the molecule. Here, we demonstrate how the combination of time-resolved spectroscopy and extensive surface hopping dynamics simulations with a global fit approach on individually excited ensembles overcomes this limitation and resolves the dynamics in the n3p Rydberg states in acetone. Photoelectron transients of the three closely spaced states n3p x, n3p y, and n3p z are used to validate the theoretical results, which in turn allow retrieving a comprehensive kinetic model describing the mutual interactions of these states for the first time.

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Revealing Ultrafast Population Transfer between Nearly Degenerate Electronic States

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