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In situ characterization of an optically thick atom-filled cavity

In situ characterization of an optically thick atom-filled cavity
In situ characterization of an optically thick atom-filled cavity

A means for precise experimental characterization of the dielectric susceptibility of an atomic gas inside an optical cavity is important for the design and operation of quantum light-matter interfaces, particularly in the context of quantum information processing. Here we present a numerically optimized theoretical model to predict the spectral response of an atom-filled cavity, accounting for both homogeneous and inhomogeneous broadening at high optical densities. We investigate the regime where the two broadening mechanisms are of similar magnitude, which makes the use of common approximations invalid. Our model agrees with an experimental implementation with warm caesium vapor in a ring cavity. From the cavity response, we are able to extract important experimental parameters, for instance the ground-state populations, total number density, and the magnitudes of both homogeneous and inhomogeneous broadening.

2469-9926
Munns, J. H.D.
a377f213-2da3-463c-924b-32122eb68c4c
Qiu, C.
28e635c9-2ac2-450f-96eb-66cc2ca8038f
Ledingham, P. M.
8db45fde-00d8-421a-93d6-7f18ac835c28
Walmsley, I. A.
a9b02ef9-f5d9-473f-ac01-bbbe06d28170
Nunn, J.
2dfa3d2a-3580-456b-962c-0d21bed9cca9
Saunders, D. J.
8d590c4e-2ea0-439c-bf42-03192c9eb60e
Munns, J. H.D.
a377f213-2da3-463c-924b-32122eb68c4c
Qiu, C.
28e635c9-2ac2-450f-96eb-66cc2ca8038f
Ledingham, P. M.
8db45fde-00d8-421a-93d6-7f18ac835c28
Walmsley, I. A.
a9b02ef9-f5d9-473f-ac01-bbbe06d28170
Nunn, J.
2dfa3d2a-3580-456b-962c-0d21bed9cca9
Saunders, D. J.
8d590c4e-2ea0-439c-bf42-03192c9eb60e

Munns, J. H.D., Qiu, C., Ledingham, P. M., Walmsley, I. A., Nunn, J. and Saunders, D. J. (2016) In situ characterization of an optically thick atom-filled cavity. Physical Review A, 93 (1), [013858]. (doi:10.1103/PhysRevA.93.013858).

Record type: Article

Abstract

A means for precise experimental characterization of the dielectric susceptibility of an atomic gas inside an optical cavity is important for the design and operation of quantum light-matter interfaces, particularly in the context of quantum information processing. Here we present a numerically optimized theoretical model to predict the spectral response of an atom-filled cavity, accounting for both homogeneous and inhomogeneous broadening at high optical densities. We investigate the regime where the two broadening mechanisms are of similar magnitude, which makes the use of common approximations invalid. Our model agrees with an experimental implementation with warm caesium vapor in a ring cavity. From the cavity response, we are able to extract important experimental parameters, for instance the ground-state populations, total number density, and the magnitudes of both homogeneous and inhomogeneous broadening.

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Published date: 29 January 2016

Identifiers

Local EPrints ID: 455413
URI: http://eprints.soton.ac.uk/id/eprint/455413
DOI: doi:10.1103/PhysRevA.93.013858
ISSN: 2469-9926
PURE UUID: 40d9acb8-335c-40d3-8e1a-23d7e19ba59a
ORCID for P. M. Ledingham: ORCID iD orcid.org/0000-0002-9804-6132

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Date deposited: 21 Mar 2022 17:41
Last modified: 17 Mar 2024 04:03

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Contributors

Author: J. H.D. Munns
Author: C. Qiu
Author: P. M. Ledingham ORCID iD
Author: I. A. Walmsley
Author: J. Nunn
Author: D. J. Saunders

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