Understanding Carotenoid Dynamics via the Vibronic Energy Relaxation Approach

Václav Šebelík; Christopher D.P. Duffy; Erika Keil; Tomáš Polívka; Jürgen Hauer

doi:10.1021/acs.jpcb.2c00996

Understanding Carotenoid Dynamics via the Vibronic Energy Relaxation Approach

Václav Šebelík, Christopher D.P. Duffy, Erika Keil, Tomáš Polívka, Jürgen Hauer

Associate Professorship of Dynamic Spectroscopy

Research output: Contribution to journal › Review article › peer-review

8 Scopus citations

Abstract

Carotenoids are an integral part of natural photosynthetic complexes, with tasks ranging from light harvesting to photoprotection. Their underlying energy deactivation network of optically dark and bright excited states is extremely efficient: after excitation of light with up to 2.5 eV of photon energy, the system relaxes back to ground state on a time scale of a few picoseconds. In this article, we summarize how a model based on the vibrational energy relaxation approach (VERA) explains the main characteristics of relaxation dynamics after one-photon excitation with special emphasis on the so-called S∗ state. Lineshapes after two-photon excitation are beyond the current model of VERA. We outline this future line of research in our article. In terms of experimental method development, we discuss which techniques are needed to better describe energy dissipation effects in carotenoids and within the first solvation shell.

Original language	English
Pages (from-to)	3985-3994
Number of pages	10
Journal	Journal of Physical Chemistry B
Volume	126
Issue number	22
DOIs	https://doi.org/10.1021/acs.jpcb.2c00996
State	Published - 9 Jun 2022

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title = "Understanding Carotenoid Dynamics via the Vibronic Energy Relaxation Approach",

abstract = "Carotenoids are an integral part of natural photosynthetic complexes, with tasks ranging from light harvesting to photoprotection. Their underlying energy deactivation network of optically dark and bright excited states is extremely efficient: after excitation of light with up to 2.5 eV of photon energy, the system relaxes back to ground state on a time scale of a few picoseconds. In this article, we summarize how a model based on the vibrational energy relaxation approach (VERA) explains the main characteristics of relaxation dynamics after one-photon excitation with special emphasis on the so-called S∗ state. Lineshapes after two-photon excitation are beyond the current model of VERA. We outline this future line of research in our article. In terms of experimental method development, we discuss which techniques are needed to better describe energy dissipation effects in carotenoids and within the first solvation shell.",

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T1 - Understanding Carotenoid Dynamics via the Vibronic Energy Relaxation Approach

AU - Šebelík, Václav

AU - Duffy, Christopher D.P.

AU - Keil, Erika

AU - Polívka, Tomáš

AU - Hauer, Jürgen

PY - 2022/6/9

Y1 - 2022/6/9

N2 - Carotenoids are an integral part of natural photosynthetic complexes, with tasks ranging from light harvesting to photoprotection. Their underlying energy deactivation network of optically dark and bright excited states is extremely efficient: after excitation of light with up to 2.5 eV of photon energy, the system relaxes back to ground state on a time scale of a few picoseconds. In this article, we summarize how a model based on the vibrational energy relaxation approach (VERA) explains the main characteristics of relaxation dynamics after one-photon excitation with special emphasis on the so-called S∗ state. Lineshapes after two-photon excitation are beyond the current model of VERA. We outline this future line of research in our article. In terms of experimental method development, we discuss which techniques are needed to better describe energy dissipation effects in carotenoids and within the first solvation shell.

AB - Carotenoids are an integral part of natural photosynthetic complexes, with tasks ranging from light harvesting to photoprotection. Their underlying energy deactivation network of optically dark and bright excited states is extremely efficient: after excitation of light with up to 2.5 eV of photon energy, the system relaxes back to ground state on a time scale of a few picoseconds. In this article, we summarize how a model based on the vibrational energy relaxation approach (VERA) explains the main characteristics of relaxation dynamics after one-photon excitation with special emphasis on the so-called S∗ state. Lineshapes after two-photon excitation are beyond the current model of VERA. We outline this future line of research in our article. In terms of experimental method development, we discuss which techniques are needed to better describe energy dissipation effects in carotenoids and within the first solvation shell.

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JF - Journal of Physical Chemistry B

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ER -

Understanding Carotenoid Dynamics via the Vibronic Energy Relaxation Approach

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