Polariton-assisted manipulation of energy relaxation pathways: donor–acceptor role reversal in a tuneable microcavity
Polariton-assisted manipulation of energy relaxation pathways: donor–acceptor role reversal in a tuneable microcavity
Resonant interaction between excitonic transitions of molecules and localized electromagnetic field allows the formation of hybrid light–matter polaritonic states. This hybridization of the light and the matter states has been shown to significantly alter the intrinsic properties of molecular ensembles placed inside the optical cavity. Here, we have observed strong coupling of excitonic transition in a pair of closely located organic dye molecules demonstrating an efficient donor-to-acceptor resonance energy transfer with the mode of a tuneable open-access cavity. Analysing the dependence of the relaxation pathways between energy states in this system on the cavity detuning, we have demonstrated that predominant strong coupling of the cavity photon to the exciton transition in the donor dye molecule can lead not only to an increase in the donor–acceptor energy transfer, but also to an energy shift large enough to cause inversion between the energy states of the acceptor and the mainly donor lower polariton energy state. Furthermore, we have shown that the polariton-assisted donor–acceptor chromophores' role reversal or “carnival effect” not only changes the relative energy levels of the donor–acceptor pair, but also makes it possible to manipulate the energy flow in the systems with resonant dipole–dipole interaction and direct energy transfer from the acceptor to the mainly donor lower polariton state. Our experimental data are the first confirmation of the theoretically predicted possibility of polariton-assisted energy transfer reversal in FRET systems, thus paving the way to new avenues in FRET-imaging, remote-controlled chemistry, and all-optical switching.
12794-12805
Dovzhenko, Dmitriy
95415e1a-b863-4462-b4bc-78f1ca490352
Lednev, Maksim
01c56b35-4b35-4b8b-9af0-2740a7a4ee9c
Mochalov, Konstantin
bcf5cfc1-60b3-4f56-97b0-2aa1570fadb6
Vaskan, Ivan
4042d007-52c2-458e-868e-5d883c34978c
Rakovich, Yury
898f9246-b36f-4906-82fe-8e0297d93a0a
Karaulov, Alexander
a442bed5-c503-4be8-b76b-61e3448af4a3
Nabiev, Igor
9c67cc2d-2b48-4196-a0f8-35f4c69c2db8
31 August 2021
Dovzhenko, Dmitriy
95415e1a-b863-4462-b4bc-78f1ca490352
Lednev, Maksim
01c56b35-4b35-4b8b-9af0-2740a7a4ee9c
Mochalov, Konstantin
bcf5cfc1-60b3-4f56-97b0-2aa1570fadb6
Vaskan, Ivan
4042d007-52c2-458e-868e-5d883c34978c
Rakovich, Yury
898f9246-b36f-4906-82fe-8e0297d93a0a
Karaulov, Alexander
a442bed5-c503-4be8-b76b-61e3448af4a3
Nabiev, Igor
9c67cc2d-2b48-4196-a0f8-35f4c69c2db8
Dovzhenko, Dmitriy, Lednev, Maksim, Mochalov, Konstantin, Vaskan, Ivan, Rakovich, Yury, Karaulov, Alexander and Nabiev, Igor
(2021)
Polariton-assisted manipulation of energy relaxation pathways: donor–acceptor role reversal in a tuneable microcavity.
Chemical Science, 12, .
(doi:10.1039/D1SC02026A).
Abstract
Resonant interaction between excitonic transitions of molecules and localized electromagnetic field allows the formation of hybrid light–matter polaritonic states. This hybridization of the light and the matter states has been shown to significantly alter the intrinsic properties of molecular ensembles placed inside the optical cavity. Here, we have observed strong coupling of excitonic transition in a pair of closely located organic dye molecules demonstrating an efficient donor-to-acceptor resonance energy transfer with the mode of a tuneable open-access cavity. Analysing the dependence of the relaxation pathways between energy states in this system on the cavity detuning, we have demonstrated that predominant strong coupling of the cavity photon to the exciton transition in the donor dye molecule can lead not only to an increase in the donor–acceptor energy transfer, but also to an energy shift large enough to cause inversion between the energy states of the acceptor and the mainly donor lower polariton energy state. Furthermore, we have shown that the polariton-assisted donor–acceptor chromophores' role reversal or “carnival effect” not only changes the relative energy levels of the donor–acceptor pair, but also makes it possible to manipulate the energy flow in the systems with resonant dipole–dipole interaction and direct energy transfer from the acceptor to the mainly donor lower polariton state. Our experimental data are the first confirmation of the theoretically predicted possibility of polariton-assisted energy transfer reversal in FRET systems, thus paving the way to new avenues in FRET-imaging, remote-controlled chemistry, and all-optical switching.
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Published date: 31 August 2021
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Local EPrints ID: 507493
URI: http://eprints.soton.ac.uk/id/eprint/507493
ISSN: 1478-6524
PURE UUID: cd4a3ff9-12aa-4510-bc13-cad75c4e8c75
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Date deposited: 10 Dec 2025 17:50
Last modified: 11 Dec 2025 02:59
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Author:
Maksim Lednev
Author:
Konstantin Mochalov
Author:
Ivan Vaskan
Author:
Yury Rakovich
Author:
Alexander Karaulov
Author:
Igor Nabiev
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