Analogue simulation of gravitational waves in a 3+1-dimensional Bose-Einstein condensate
Analogue simulation of gravitational waves in a 3+1-dimensional Bose-Einstein condensate
The recent detections of gravitational waves (GWs) by the LIGO and Virgo collaborations have opened the field of GW astronomy, intensifying interest in GWs and other possible detectors sensitive in different frequency ranges. Although strong GW producing events are rare and currently unpredictable, GWs can in principle be simulated in analogue systems at will in the lab. Simulation of GWs in a manifestly quantum system would allow for the study of the interaction of quantum phenomena with GWs. Such predicted interaction is exploited in a recently proposed Bose-Einstein condensate (BEC) based GW detector. In this paper, we show how to manipulate a BEC to mimic the effect of a passing GW. By simultaneously varying the external potential applied to the BEC, and an external magnetic field near a Feshbach resonance, we show that the resulting change in speed of sound can directly reproduce a GW metric. We also show how to simulate a metric used in the recently proposed BEC based GW detector, to provide an environment for testing the proposed metrology scheme of the detector. Explicit expressions for simulations of various GW sources are given. This result is also useful to generally test the interaction of quantum phenomena with GWs in a curved spacetime analogue experiment.
Hartley, Daniel
33e128eb-862c-4efc-b562-508c3b595f07
Bravo, Tupac
7f9c92af-bc61-4922-9ea6-3f0c03479861
Raetzel, Dennis
2f8dae44-7029-43c9-9183-683e2da75269
Howl, Richard
0856300a-849c-41af-b124-65947cca1cad
Fuentes, Ivette
c6d65a4c-feac-44c1-9097-e0f6a9e0cf44
17 July 2018
Hartley, Daniel
33e128eb-862c-4efc-b562-508c3b595f07
Bravo, Tupac
7f9c92af-bc61-4922-9ea6-3f0c03479861
Raetzel, Dennis
2f8dae44-7029-43c9-9183-683e2da75269
Howl, Richard
0856300a-849c-41af-b124-65947cca1cad
Fuentes, Ivette
c6d65a4c-feac-44c1-9097-e0f6a9e0cf44
Hartley, Daniel, Bravo, Tupac, Raetzel, Dennis, Howl, Richard and Fuentes, Ivette
(2018)
Analogue simulation of gravitational waves in a 3+1-dimensional Bose-Einstein condensate.
Physical Review D, 98 (2), [025011].
(doi:10.1103/PhysRevD.98.025011).
Abstract
The recent detections of gravitational waves (GWs) by the LIGO and Virgo collaborations have opened the field of GW astronomy, intensifying interest in GWs and other possible detectors sensitive in different frequency ranges. Although strong GW producing events are rare and currently unpredictable, GWs can in principle be simulated in analogue systems at will in the lab. Simulation of GWs in a manifestly quantum system would allow for the study of the interaction of quantum phenomena with GWs. Such predicted interaction is exploited in a recently proposed Bose-Einstein condensate (BEC) based GW detector. In this paper, we show how to manipulate a BEC to mimic the effect of a passing GW. By simultaneously varying the external potential applied to the BEC, and an external magnetic field near a Feshbach resonance, we show that the resulting change in speed of sound can directly reproduce a GW metric. We also show how to simulate a metric used in the recently proposed BEC based GW detector, to provide an environment for testing the proposed metrology scheme of the detector. Explicit expressions for simulations of various GW sources are given. This result is also useful to generally test the interaction of quantum phenomena with GWs in a curved spacetime analogue experiment.
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Published date: 17 July 2018
Identifiers
Local EPrints ID: 479335
URI: http://eprints.soton.ac.uk/id/eprint/479335
ISSN: 2470-0010
PURE UUID: 66b87929-ee71-4835-a64a-e3b5a672c1a1
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Date deposited: 20 Jul 2023 17:27
Last modified: 17 Mar 2024 00:33
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Author:
Daniel Hartley
Author:
Tupac Bravo
Author:
Dennis Raetzel
Author:
Richard Howl
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