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Frequency spectrum of an optical resonator in a curved spacetime

Frequency spectrum of an optical resonator in a curved spacetime
Frequency spectrum of an optical resonator in a curved spacetime
The effect of gravity and proper acceleration on the frequency spectrum of an optical resonator—both rigid or deformable—is considered in the framework of general relativity. The optical resonator is modeled either as a rod of matter connecting two mirrors or as a dielectric rod whose ends function as mirrors. Explicit expressions for the frequency spectrum are derived for the case that it is only perturbed slightly and variations are slow enough to avoid any elastic resonances of the rod. For a deformable resonator, the perturbation of the frequency spectrum depends on the speed of sound in the rod supporting the mirrors. A connection is found to a relativistic concept of rigidity when the speed of sound approaches the speed of light. In contrast, the corresponding result for the assumption of Born rigidity is recovered when the speed of sound becomes infinite. The results presented in this article can be used as the basis for the description of optical and opto-mechanical systems in a curved spacetime. We apply our results to the examples of a uniformly accelerating resonator and an optical resonator in the gravitational field of a small moving sphere. To exemplify the applicability of our approach beyond the framework of linearized gravity, we consider the fictitious situation of an optical resonator falling into a black hole.
gravitational field, rigid rod, frequency spectrum, Fabry-Perot, elastic body, optical cavity, geometrical optics
1367-2630
Raetzel, Dennis
2f8dae44-7029-43c9-9183-683e2da75269
Schneiter, Fabienne
0317d29f-63e8-4c9e-a75b-48171591d9aa
Braun, Daniel
946e5baf-e36a-4360-b086-5342bb0c869b
Bravo, Tupac
7f9c92af-bc61-4922-9ea6-3f0c03479861
Howl, Richard
0856300a-849c-41af-b124-65947cca1cad
Lock, Maximilian P. E.
41665dcd-aac1-49d9-a46f-594a6e24b30d
Fuentes, Ivette
c6d65a4c-feac-44c1-9097-e0f6a9e0cf44
Raetzel, Dennis
2f8dae44-7029-43c9-9183-683e2da75269
Schneiter, Fabienne
0317d29f-63e8-4c9e-a75b-48171591d9aa
Braun, Daniel
946e5baf-e36a-4360-b086-5342bb0c869b
Bravo, Tupac
7f9c92af-bc61-4922-9ea6-3f0c03479861
Howl, Richard
0856300a-849c-41af-b124-65947cca1cad
Lock, Maximilian P. E.
41665dcd-aac1-49d9-a46f-594a6e24b30d
Fuentes, Ivette
c6d65a4c-feac-44c1-9097-e0f6a9e0cf44

Raetzel, Dennis, Schneiter, Fabienne, Braun, Daniel, Bravo, Tupac, Howl, Richard, Lock, Maximilian P. E. and Fuentes, Ivette (2018) Frequency spectrum of an optical resonator in a curved spacetime. New Journal of Physics, 20, [053046]. (doi:10.1088/1367-2630/aac0ac).

Record type: Article

Abstract

The effect of gravity and proper acceleration on the frequency spectrum of an optical resonator—both rigid or deformable—is considered in the framework of general relativity. The optical resonator is modeled either as a rod of matter connecting two mirrors or as a dielectric rod whose ends function as mirrors. Explicit expressions for the frequency spectrum are derived for the case that it is only perturbed slightly and variations are slow enough to avoid any elastic resonances of the rod. For a deformable resonator, the perturbation of the frequency spectrum depends on the speed of sound in the rod supporting the mirrors. A connection is found to a relativistic concept of rigidity when the speed of sound approaches the speed of light. In contrast, the corresponding result for the assumption of Born rigidity is recovered when the speed of sound becomes infinite. The results presented in this article can be used as the basis for the description of optical and opto-mechanical systems in a curved spacetime. We apply our results to the examples of a uniformly accelerating resonator and an optical resonator in the gravitational field of a small moving sphere. To exemplify the applicability of our approach beyond the framework of linearized gravity, we consider the fictitious situation of an optical resonator falling into a black hole.

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More information

Accepted/In Press date: 27 April 2018
Published date: 18 May 2018
Keywords: gravitational field, rigid rod, frequency spectrum, Fabry-Perot, elastic body, optical cavity, geometrical optics
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Identifiers

Local EPrints ID: 479333
URI: http://eprints.soton.ac.uk/id/eprint/479333
DOI: doi:10.1088/1367-2630/aac0ac
ISSN: 1367-2630
PURE UUID: 80ec7b53-107e-45e9-8d30-b8bea1ed6414

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Date deposited: 20 Jul 2023 17:27
Last modified: 17 Mar 2024 00:33

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Contributors

Author: Dennis Raetzel
Author: Fabienne Schneiter
Author: Daniel Braun
Author: Tupac Bravo
Author: Richard Howl
Author: Maximilian P. E. Lock
Author: Ivette Fuentes

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