Gravitational time dilation in extended quantum systems: The case of light clocks in Schwarzschild spacetime
Gravitational time dilation in extended quantum systems: The case of light clocks in Schwarzschild spacetime
The precision of optical atomic clocks is approaching a regime where they resolve gravitational time dilation on smaller scales than their own extensions. Hence, an accurate description of quantum clocks has to take their spatial extension into account. In this article, as a first step toward a fully relativistic description of extended quantum clocks, we investigate a quantized version of Einstein's light clock fixed at a constant distance from a large massive object like the Earth. The model consists of a quantum light field in a one-dimensional cavity in Schwarzschild spacetime, where the distance between the mirrors is fixed by a rigid rod. By comparing a vertical and a horizontal clock, we propose an operational way to define the clock time when the clock resolves gravitational time dilation on scales smaller than its extension. In particular, we show that the time measured by the vertical light clock is equivalent to the proper time defined at its center. We also derive fundamental bounds on the precision of these clocks for measurements of proper time and the Schwarzschild radius.
Bravo, Tupac
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Rätzel, Dennis
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Fuentes, Ivette
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1 March 2023
Bravo, Tupac
7f9c92af-bc61-4922-9ea6-3f0c03479861
Rätzel, Dennis
ab613c70-8628-405a-a01a-a19ec9fd8d86
Fuentes, Ivette
c6d65a4c-feac-44c1-9097-e0f6a9e0cf44
Bravo, Tupac, Rätzel, Dennis and Fuentes, Ivette
(2023)
Gravitational time dilation in extended quantum systems: The case of light clocks in Schwarzschild spacetime.
AVS Quantum Science, 5 (1), [014401].
(doi:10.1116/5.0123228).
Abstract
The precision of optical atomic clocks is approaching a regime where they resolve gravitational time dilation on smaller scales than their own extensions. Hence, an accurate description of quantum clocks has to take their spatial extension into account. In this article, as a first step toward a fully relativistic description of extended quantum clocks, we investigate a quantized version of Einstein's light clock fixed at a constant distance from a large massive object like the Earth. The model consists of a quantum light field in a one-dimensional cavity in Schwarzschild spacetime, where the distance between the mirrors is fixed by a rigid rod. By comparing a vertical and a horizontal clock, we propose an operational way to define the clock time when the clock resolves gravitational time dilation on scales smaller than its extension. In particular, we show that the time measured by the vertical light clock is equivalent to the proper time defined at its center. We also derive fundamental bounds on the precision of these clocks for measurements of proper time and the Schwarzschild radius.
Text
Gravitational time dilation in extended quantum systems the case of light clocks in Schwarzschild spacetime
- Accepted Manuscript
Text
Gravitational time dilation in extended quantum systems the case of light clocks in Schwarzschild spacetime
- Accepted Manuscript
More information
Accepted/In Press date: 14 November 2022
Published date: 1 March 2023
Additional Information:
Funding Information:
We acknowledge Richard Howl, Luis Cortés Barbado, Maximilian Lock, Jorma Louko, Héctor Fernández Melendez, and David Edward Bruschi for useful comments and considerations. T.B. acknowledges funding from CONACYT under project code 261699/359033. I.F. acknowledges that this project was made possible through the support of a donation by John Moussouris and the grant “Leaps in cosmology: Gravitational wave detection with quantum systems” (No. 58745) from the John Templeton Foundation. D.R. thanks the Humboldt Foundation for supporting his work by awarding him their Feodor Lynen Research Fellowship and acknowledges funding by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) under Germany's Excellence Strategy—EXC-2123 QuantumFrontiers—No. 390837967 and by the Federal Ministry of Education and Research of Germany in the project “Open6GHub” (Grant No.: 16KISK016). This work was in part supported by the Anglo-Austrian Society.
Published under an exclusive license by AIP Publishing, https://doi.org/10.1116/5.0123228
© 2023 Author(s).
arXiv:2204.07869V3
Identifiers
Local EPrints ID: 477933
URI: http://eprints.soton.ac.uk/id/eprint/477933
ISSN: 2639-0213
PURE UUID: 832c66b3-4914-43b2-ae8b-0072b4ad6343
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Date deposited: 16 Jun 2023 16:45
Last modified: 17 Mar 2024 13:15
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Author:
Tupac Bravo
Author:
Dennis Rätzel
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