A first-order deconfinement phase transition in the early universe and gravitational waves
A first-order deconfinement phase transition in the early universe and gravitational waves
We clarify the conditions of the cosmic quantum chromodynamics (QCD) first-order phase transition in the early universe by carefully distinguishing the chiral and deconfinement phase transitions. While the chiral one with light quarks at zero chemical potential is unlikely to be first order based on the recent lattice QCD calculations, the latter one can be naturally extended with one extra rolling scalar to be first order. The argument is also valid for the dark QCD theory with arbitrary Nc with a wide range of phase transition temperatures, which can be from hundreds of MeV up to beyond TeV. Notably, here we derive the general formula for the deconfinement phase transition potential of SU(Nc) gauge theory characterized by the Polyakov loop. With the effective potential in hand, the gravitational wave spectrum is then determined via the sound shell model, which then enables us to give for the first time the quantitative analysis of the gravitational wave signals coming from the QCD deconfinement phase transition and awaits the check from future space interferometers.
hep-ph, astro-ph.CO, hep-th, nucl-th
Gao, Fei
fa3e4707-8319-49fa-897b-b27f7a534508
Sun, Sichun
c5776cbb-8fc4-4e4c-8c9f-e7ffa5d17d3e
White, Graham
652445c5-e1e5-4ff7-84e1-a3bca45e75d0
Gao, Fei
fa3e4707-8319-49fa-897b-b27f7a534508
Sun, Sichun
c5776cbb-8fc4-4e4c-8c9f-e7ffa5d17d3e
White, Graham
652445c5-e1e5-4ff7-84e1-a3bca45e75d0
[Unknown type: UNSPECIFIED]
Abstract
We clarify the conditions of the cosmic quantum chromodynamics (QCD) first-order phase transition in the early universe by carefully distinguishing the chiral and deconfinement phase transitions. While the chiral one with light quarks at zero chemical potential is unlikely to be first order based on the recent lattice QCD calculations, the latter one can be naturally extended with one extra rolling scalar to be first order. The argument is also valid for the dark QCD theory with arbitrary Nc with a wide range of phase transition temperatures, which can be from hundreds of MeV up to beyond TeV. Notably, here we derive the general formula for the deconfinement phase transition potential of SU(Nc) gauge theory characterized by the Polyakov loop. With the effective potential in hand, the gravitational wave spectrum is then determined via the sound shell model, which then enables us to give for the first time the quantitative analysis of the gravitational wave signals coming from the QCD deconfinement phase transition and awaits the check from future space interferometers.
Text
2405.00490v1
- Author's Original
Available under License Other.
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Accepted/In Press date: 1 May 2024
Additional Information:
6 pages, 2 figures
Keywords:
hep-ph, astro-ph.CO, hep-th, nucl-th
Identifiers
Local EPrints ID: 490029
URI: http://eprints.soton.ac.uk/id/eprint/490029
PURE UUID: d0ec4b69-391b-4274-949e-6ad74675356b
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Date deposited: 14 May 2024 16:30
Last modified: 14 May 2024 16:30
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Contributors
Author:
Fei Gao
Author:
Sichun Sun
Author:
Graham White
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