Transition rate and gravitational wave spectrum from first-order QCD phase transitions

Abstract

We investigate the gravitational wave spectrum induced by first-order QCD phase transitions including the deconfinement phase transition in the pure gluon system and Friedberg-Lee model, and chiral phase transition in the quark-meson model and Polyakov quark-meson model. The gravitational wave power spectra are sensitive to the phase transition rate β/H. All QCD models predict a rather large phase transition rate in the order of β/H104 at high temperature region, and the produced gravitational waves lie in the peak frequency region of 10-4-0.01 Hz, corresponding to an energy spectrum in the range of 10-8-10-7, which can be detected by LISA and Taiji. If a high baryon density is generated through Affleck-Dine baryogenesis or other mechanisms, the baryon chemical potential significantly reduces the phase transition rate, potentially dropping it to the order of β/H 101, leading to the production of nanohertz gravitational waves. Furthermore, a critical quark chemical potential exists with a zero phase transition rate β/H=0, indicating that the false vacuum will not decay, thus supporting the formation of primordial quark nuggets in the early universe.

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