Baryogenesis and first-order QCD transition with gravitational waves from a large lepton asymmetry
Baryogenesis and first-order QCD transition with gravitational waves from a large lepton asymmetry
A large primordial lepton asymmetry can lead to successful baryogenesis by preventing the restoration of electroweak symmetry at high temperatures, thereby suppressing the sphaleron rate. This asymmetry can also lead to a first-order cosmic QCD transition, accompanied by detectable gravitational wave (GW) signals. By employing next-to-leading order dimensional reduction we determine that the necessary lepton asymmetry is approximately one order of magnitude smaller than previously estimated. Incorporating an updated QCD equation of state that harmonizes lattice and functional QCD outcomes, we pinpoint the range of lepton flavor asymmetries capable of inducing a first-order cosmic QCD transition. To maintain consistency with observational constraints from the Cosmic Microwave Background and Big Bang Nucleosynthesis, achieving the correct baryon asymmetry requires entropy dilution by approximately a factor of ten. However, the first-order QCD transition itself can occur independently of entropy dilution. We propose that the sphaleron freeze-in mechanism can be investigated through forthcoming GW experiments such as μAres
hep-ph, astro-ph.CO, 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
07b0a8ac-e793-4457-84e5-847870075994
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
07b0a8ac-e793-4457-84e5-847870075994
Oldengott, Isabel M.
fe19a7e7-876d-493b-9d48-1edc7b08a67f
White, Graham
652445c5-e1e5-4ff7-84e1-a3bca45e75d0
[Unknown type: UNSPECIFIED]
Abstract
A large primordial lepton asymmetry can lead to successful baryogenesis by preventing the restoration of electroweak symmetry at high temperatures, thereby suppressing the sphaleron rate. This asymmetry can also lead to a first-order cosmic QCD transition, accompanied by detectable gravitational wave (GW) signals. By employing next-to-leading order dimensional reduction we determine that the necessary lepton asymmetry is approximately one order of magnitude smaller than previously estimated. Incorporating an updated QCD equation of state that harmonizes lattice and functional QCD outcomes, we pinpoint the range of lepton flavor asymmetries capable of inducing a first-order cosmic QCD transition. To maintain consistency with observational constraints from the Cosmic Microwave Background and Big Bang Nucleosynthesis, achieving the correct baryon asymmetry requires entropy dilution by approximately a factor of ten. However, the first-order QCD transition itself can occur independently of entropy dilution. We propose that the sphaleron freeze-in mechanism can be investigated through forthcoming GW experiments such as μAres
Text
2407.17549v1
- Author's Original
Available under License Other.
More information
Accepted/In Press date: 24 July 2024
Additional Information:
50 pages, 9 figures
Keywords:
hep-ph, astro-ph.CO, hep-th
Identifiers
Local EPrints ID: 496288
URI: http://eprints.soton.ac.uk/id/eprint/496288
PURE UUID: 57127041-e461-458e-852f-377918eaacb3
Catalogue record
Date deposited: 10 Dec 2024 18:05
Last modified: 10 Dec 2024 18:05
Export record
Altmetrics
Contributors
Author:
Fei Gao
Author:
Julia Harz
Author:
Chandan Hati
Author:
Yi Lu
Author:
Isabel M. Oldengott
Author:
Graham White
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics