Testing the dark SU(N) Yang-Mills theory confined landscape: From the lattice to gravitational waves

Wei Chih Huang; Manuel Reichert; Francesco Sannino; Zhi Wei Wang

doi:10.1103/PhysRevD.104.035005

Testing the dark SU(N) Yang-Mills theory confined landscape: From the lattice to gravitational waves

Wei Chih Huang, Manuel Reichert, Francesco Sannino, Zhi Wei Wang^*

^*Corresponding author for this work

Department of Physics, Chemistry and Pharmacy

Research output: Contribution to journal › Journal article › Research › peer-review

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Abstract

We pave the way for future gravitational-wave detection experiments, such as the big bang observer and DECIGO, to constraint 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 nonperturbative 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.

Original language	English
Article number	035005
Journal	Physical Review D
Volume	104
Issue number	3
Number of pages	17
ISSN	2470-0010
DOIs	https://doi.org/10.1103/PhysRevD.104.035005
Publication status	Published - 1. Aug 2021

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© 2021 authors. Published by the American Physical Society.

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Open Access VersionFinal published version, 2.29 MBLicence: CC BY

https://arxiv.org/pdf/2012.11614

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abstract = "We pave the way for future gravitational-wave detection experiments, such as the big bang observer and DECIGO, to constraint 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 nonperturbative 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.",

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AU - Wang, Zhi Wei

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N2 - We pave the way for future gravitational-wave detection experiments, such as the big bang observer and DECIGO, to constraint 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 nonperturbative 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.

AB - We pave the way for future gravitational-wave detection experiments, such as the big bang observer and DECIGO, to constraint 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 nonperturbative 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.

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Testing the dark SU(N) Yang-Mills theory confined landscape: From the lattice to gravitational waves

Abstract

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