Spontaneous breaking of global U(1) symmetry in an interacting Bose gas under rigid rotation

Abstract

We investigate the impact of rigid rotation on the spontaneous breaking of U(1) symmetry in a Bose gas, which is described by a self-interacting complex scalar field Lagrangian. Rigid rotation is introduced through a specific metric that explicitly depends on the angular velocity . We begin by determining the free propagator for this model at finite temperature T and chemical potential μ. Using this propagator, we calculate the thermodynamic potential in terms of an energy dispersion relation εk. It is found that in both the U(1) symmetric phase and the symmetry-broken phase, two energy branches emerge. In the symmetry-broken phase, they are identified with a massive phonon and a massless roton mode. Notably, rotation does not alter εk at low momentum. Setting μ=0, we use the total thermodynamic potential, which includes classical, thermal, vacuum, and nonperturbative ring contributions, to explore how the condensate depends on T and . We first focus on the classical and thermal parts of the thermodynamic potential and find that the critical temperature of the U(1) phase transition scales as 1/3. By identifying the (pseudo-)Goldstone and non-Goldstone modes of this model with π and σ mesons, we calculate the T and dependence of masses mπ and mσ. We demonstrate that the Goldstone theorem holds only when the one-loop (thermal) corrections to mσ and mπ are taken into account. We further explore the T and dependence of the condensate, determine the σ dissociation temperatures for fixed , and compare them with the critical temperature of the phase transition. Additionally, we emphasize the role played by the nonperturbative ring potential, especially in altering the order of the phase transition with and without rotation.