PhysRevD.104.035005.pdf (2.29 MB)
Testing the dark SU(N) Yang-Mills theory confined landscape: from the lattice to gravitational waves
Version 2 2023-06-12, 09:59
Version 1 2023-06-10, 00:48
journal contribution
posted on 2023-06-12, 09:59 authored by Wei-Chih Huang, Manuel ReichertManuel Reichert, Francesco Sannino, Zhi-Wei WangWe pave the way for future gravitational-wave detection experiments, such as the Big Bang Observer and DECIGO, to constrain dark sectors made of SU(N) Yang-Mills confined theories. We go beyond the state-of-the-art by combining first principle lattice results and effective field theory approaches to infer essential information about the non-perturbative dark deconfinement phase transition driving the generation of gravitational-waves in the early universe, such as the order, duration and energy budget of the phase transition which are essential in establishing the strength of the resulting gravitational-wave signal.
Funding
Science and Technology Research Council; ST/T00102X/1
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Publication status
- Published
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- Published version
Journal
Physical Review DISSN
2470-0010Publisher
American Physical SocietyExternal DOI
Issue
3Volume
104Page range
1-17Article number
a035005Department affiliated with
- Physics and Astronomy Publications
Research groups affiliated with
- Theoretical Particle Physics Research Group Publications
Full text available
- Yes
Peer reviewed?
- Yes
Legacy Posted Date
2021-08-31First Open Access (FOA) Date
2021-08-31First Compliant Deposit (FCD) Date
2021-08-27Usage metrics
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