Gravitating bubbles of gluon plasma above deconfinement temperature

Abstract

The equation of state of SU(3) Yang-Mills theory can be modelled by an effective Z3-symmetric potential V(φ,φ3+φ3*, T) depending on the temperature T and on a scalar field φ -- the averaged Polyakov loop. Allowing φ to be dynamical opens the way to the study of spatially localized classical configurations of the Polyakov loop. We first show that spherically symmetric static Q-balls exist in the range (1-1.21)× Tc, Tc being the deconfinement temperature. Then we argue that Q-holes solutions, if any are unphysical within our framework. Finally we couple the Polyakov-loop Lagrangian to Einstein gravity and show that spherically symmetric static boson stars exist in the same range of temperature. The Q-ball and boson star solutions we find can be interpreted as "bubbles" of deconfined gluonic matter; their mean radius is always smaller than 10 fm.