Strong coupling dynamics of driven quantum systems with permanent dipoles
Strong coupling dynamics of driven quantum systems with permanent dipoles
Many optically active systems possess spatially asymmetric electron orbitals. These generate permanent dipole moments, which can be stronger than the corresponding transition dipole moments, significantly affecting the system dynamics and creating polarized Fock states of light. We derive a master equation for these systems with an externally applied driving field by employing an optical polaron transformation that captures the photon mode polarization induced by the permanent dipoles. This provides an intuitive framework to explore their influence on the system dynamics and emission spectrum. We find that permanent dipoles introduce multiple-photon processes and a photon sideband, which causes substantial modifications to single-photon transition dipole processes. In the presence of an external drive, permanent dipoles lead to an additional process that we show can be exploited to control the decoherence and transition rates. We derive the emission spectrum of the system, highlighting experimentally detectable signatures of optical polarons, and measurements that can identify the parameters in the system Hamiltonian, the magnitude of the differences in the permanent dipoles, and the steady-state populations of the system.
Burgess, A.
7ec0ced9-91e1-4983-a3d7-2153d68a4db2
Florescu, M.
14b7415d-9dc6-4ebe-a125-289e47648c65
Rouse, D.M.
667602df-2d49-4dd5-92b5-bae8ed066b4d
28 September 2023
Burgess, A.
7ec0ced9-91e1-4983-a3d7-2153d68a4db2
Florescu, M.
14b7415d-9dc6-4ebe-a125-289e47648c65
Rouse, D.M.
667602df-2d49-4dd5-92b5-bae8ed066b4d
Burgess, A., Florescu, M. and Rouse, D.M.
(2023)
Strong coupling dynamics of driven quantum systems with permanent dipoles.
AVS Quantum Science, 5, [031402].
(doi:10.1116/5.0157714).
Abstract
Many optically active systems possess spatially asymmetric electron orbitals. These generate permanent dipole moments, which can be stronger than the corresponding transition dipole moments, significantly affecting the system dynamics and creating polarized Fock states of light. We derive a master equation for these systems with an externally applied driving field by employing an optical polaron transformation that captures the photon mode polarization induced by the permanent dipoles. This provides an intuitive framework to explore their influence on the system dynamics and emission spectrum. We find that permanent dipoles introduce multiple-photon processes and a photon sideband, which causes substantial modifications to single-photon transition dipole processes. In the presence of an external drive, permanent dipoles lead to an additional process that we show can be exploited to control the decoherence and transition rates. We derive the emission spectrum of the system, highlighting experimentally detectable signatures of optical polarons, and measurements that can identify the parameters in the system Hamiltonian, the magnitude of the differences in the permanent dipoles, and the steady-state populations of the system.
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Accepted/In Press date: 5 September 2023
Published date: 28 September 2023
Identifiers
Local EPrints ID: 501306
URI: http://eprints.soton.ac.uk/id/eprint/501306
ISSN: 2639-0213
PURE UUID: b85e8f42-4c5e-43c7-97dc-9e12a17a54d1
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Date deposited: 28 May 2025 16:59
Last modified: 29 May 2025 02:16
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Author:
A. Burgess
Author:
M. Florescu
Author:
D.M. Rouse
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