Abelian Higgs gauge theories with multicomponent scalar fields and multiparameter scalar potentials
Abstract
We consider multicomponent Abelian Higgs (AH) gauge theories with multiparameter scalar quartic potentials that are extensions, with a smaller global symmetry group, of SU(N)-invariant AH theories. In particular, we consider an AH model with a two-parameter scalar potential and SO(N) global symmetry. We discuss the renormalization-group flow of the SO(N)-invariant AH field theory and the phase diagram and critical behavior of a corresponding three-dimensional (3D) noncompact lattice AH model. We argue that the phase diagram of 3D noncompact SO(N)- and SU(N)-symmetric lattice AH models are qualitatively similar. In both cases there are three phases: the high-temperature Coulomb phase, and the low-temperature molecular and Higgs phases that differ for the topological properties of the gauge correlations. However, the main features of the low-temperature ordered phases, and in particular of the Higgs phase, differ significantly in SO(N) and SU(N) models. In particular, in SO(N) models they depend on the sign of the self-interaction parameter v that controls the symmetry breaking from SU(N) to SO(N). As a consequence, also the universal features of the transitions related with the spontaneous breaking of the global symmetry (those between the high-temperature Coulomb phase and the low-temperature molecular and Higgs phases) depend on the sign of v.
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