Gravitational Waves from Confinement in SU(N) Yang-Mills Theory
Abstract
We provide a detailed analysis of the gravitational wave spectrum of SU(N) pure Yang-Mills theory. The confinement phase transition is described with an effective Polyakov loop model, using the latest lattice data as an input. In particular, recent lattice studies clarified the large-N scaling of the surface tension, which we incorporate through a modification of the kinetic term. We demonstrate that the thin-wall approximation agrees with the Polyakov loop model at small N while it breaks down at large N. Furthermore, we include reliable estimates of the bubble wall velocity using a recently developed framework based on a large enthalpy jump at the phase transition. Altogether, this allows us to derive the gravitational wave signals for all SU(N) confinement phase transitions and clarifies the behaviour at large N. The strongest signal arises for N=20, but overall the predicted signals remain rather weak. Our work paves the way for future studies of other gauge groups and systems with fermions.
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