Non-thermal production of heavy vector dark matter from relativistic bubble walls
Non-thermal production of heavy vector dark matter from relativistic bubble walls
Heavy vector boson dark matter at the TeV scale or higher may be produced non-thermally in a first-order phase transition taking place at a lower energy scale. While the production of vector dark matter has previously been studied for bubble wall collisions, here we calculate production by bubble wall expansion in a plasma, which can be the dominant production mechanism. We compute the results numerically and provide an analytical fit for the vector dark matter density. The numerical fit is also validated for scalar dark matter production, obtaining results in agreement with past literature. We find that vector pair production leads to bubble wall friction with a novel boost factor scaling behaviour compared to transition radiation emission of a single vector. We conclude that TeV-scale WIMP vector dark matter can be efficiently produced non-thermally by first-order phase transitions in a wide region of parameter space where thermal freeze-out is inefficient. In this scenario, the phase transition scale is predicted to be in the sub-GeV to O(10) TeV range and could therefore be accessible to future gravitational wave detectors.
hep-ph, astro-ph.CO
Ai, Wen-Yuan
4b6fa14f-efd0-422a-9d40-0a4493b17c29
Fairbairn, Malcolm
d18edc59-3310-4348-9af4-2f8625caddbd
Mimasu, Ken
be4d4828-5d71-4c3f-a8d1-81d62a9d2e33
You, Tevong
adb904b4-9188-4227-bb39-99059c42dc29
Ai, Wen-Yuan
4b6fa14f-efd0-422a-9d40-0a4493b17c29
Fairbairn, Malcolm
d18edc59-3310-4348-9af4-2f8625caddbd
Mimasu, Ken
be4d4828-5d71-4c3f-a8d1-81d62a9d2e33
You, Tevong
adb904b4-9188-4227-bb39-99059c42dc29
[Unknown type: UNSPECIFIED]
Abstract
Heavy vector boson dark matter at the TeV scale or higher may be produced non-thermally in a first-order phase transition taking place at a lower energy scale. While the production of vector dark matter has previously been studied for bubble wall collisions, here we calculate production by bubble wall expansion in a plasma, which can be the dominant production mechanism. We compute the results numerically and provide an analytical fit for the vector dark matter density. The numerical fit is also validated for scalar dark matter production, obtaining results in agreement with past literature. We find that vector pair production leads to bubble wall friction with a novel boost factor scaling behaviour compared to transition radiation emission of a single vector. We conclude that TeV-scale WIMP vector dark matter can be efficiently produced non-thermally by first-order phase transitions in a wide region of parameter space where thermal freeze-out is inefficient. In this scenario, the phase transition scale is predicted to be in the sub-GeV to O(10) TeV range and could therefore be accessible to future gravitational wave detectors.
Text
2406.20051v1
- Author's Original
More information
Accepted/In Press date: 28 June 2024
Additional Information:
39 pages, 13 figures
Keywords:
hep-ph, astro-ph.CO
Identifiers
Local EPrints ID: 496243
URI: http://eprints.soton.ac.uk/id/eprint/496243
PURE UUID: d9e68a3a-f4dd-47cb-b06a-89830c556534
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Date deposited: 09 Dec 2024 17:52
Last modified: 10 Dec 2024 03:08
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Contributors
Author:
Wen-Yuan Ai
Author:
Malcolm Fairbairn
Author:
Ken Mimasu
Author:
Tevong You
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