Sphaleron freeze-in baryogenesis with gravitational waves from the QCD transition
Sphaleron freeze-in baryogenesis with gravitational waves from the QCD transition
A large primordial lepton asymmetry is capable of explaining the baryon asymmetry of the Universe (BAU) through suppression of the electroweak sphaleron rates (``sphaleron freeze-in") which can lead to a first-order cosmic QCD transition with an observable gravitational wave (GW) signal. With next-to-leading order dimensional reduction and the exact 1-loop fluctuation determinant, we accurately compute the lepton asymmetry needed to realize this paradigm, finding it to be an order of magnitude smaller than previous estimates. Further, we apply an improved QCD equation of state capable of describing the phase transition line together with the critical endpoint leading to better agreement with lattice and functional QCD results. Based on this, we identify the range of lepton flavor asymmetries inducing a first-order cosmic QCD transition. We then extract the parameters relevant to the prediction of GW signal from a first-order cosmic QCD transition. Our result showcases the possibility of probing the sphaleron freeze-in paradigm as an explanation of BAU by future gravitational wave experiments like μAres.
hep-ph, astro-ph.CO, astro-ph.HE, hep-th
Gao, Fei
fa3e4707-8319-49fa-897b-b27f7a534508
Harz, Julia
fabe899e-3ad4-4e0a-9751-9b4c87a1c79c
Hati, Chandan
bac80b22-506b-48cf-8f5a-9b67bd56bb27
Lu, Yi
ca6ad963-5143-42a4-87a1-9503a8467ca2
Oldengott, Isabel M.
fe19a7e7-876d-493b-9d48-1edc7b08a67f
White, Graham
652445c5-e1e5-4ff7-84e1-a3bca45e75d0
Gao, Fei
fa3e4707-8319-49fa-897b-b27f7a534508
Harz, Julia
fabe899e-3ad4-4e0a-9751-9b4c87a1c79c
Hati, Chandan
bac80b22-506b-48cf-8f5a-9b67bd56bb27
Lu, Yi
ca6ad963-5143-42a4-87a1-9503a8467ca2
Oldengott, Isabel M.
fe19a7e7-876d-493b-9d48-1edc7b08a67f
White, Graham
652445c5-e1e5-4ff7-84e1-a3bca45e75d0
[Unknown type: UNSPECIFIED]
Abstract
A large primordial lepton asymmetry is capable of explaining the baryon asymmetry of the Universe (BAU) through suppression of the electroweak sphaleron rates (``sphaleron freeze-in") which can lead to a first-order cosmic QCD transition with an observable gravitational wave (GW) signal. With next-to-leading order dimensional reduction and the exact 1-loop fluctuation determinant, we accurately compute the lepton asymmetry needed to realize this paradigm, finding it to be an order of magnitude smaller than previous estimates. Further, we apply an improved QCD equation of state capable of describing the phase transition line together with the critical endpoint leading to better agreement with lattice and functional QCD results. Based on this, we identify the range of lepton flavor asymmetries inducing a first-order cosmic QCD transition. We then extract the parameters relevant to the prediction of GW signal from a first-order cosmic QCD transition. Our result showcases the possibility of probing the sphaleron freeze-in paradigm as an explanation of BAU by future gravitational wave experiments like μAres.
Text
2309.00672v1
- Author's Original
Available under License Other.
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Accepted/In Press date: 1 September 2023
Additional Information:
3 figures
Keywords:
hep-ph, astro-ph.CO, astro-ph.HE, hep-th
Identifiers
Local EPrints ID: 483260
URI: http://eprints.soton.ac.uk/id/eprint/483260
PURE UUID: 0f87326d-0f22-4d29-8ab3-762856ec65e8
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Date deposited: 26 Oct 2023 17:09
Last modified: 17 Mar 2024 05:09
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Contributors
Author:
Fei Gao
Author:
Julia Harz
Author:
Chandan Hati
Author:
Yi Lu
Author:
Isabel M. Oldengott
Author:
Graham White
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