Effective potential and dynamical symmetry breaking up to five loops in a massless abelian Higgs model

TL;DR

This paper calculates the effective potential up to five loops in a massless Abelian Higgs model using the Renormalization Group Equation, revealing complex vacuum structures and symmetry breaking mechanisms.

Contribution

It extends the effective potential calculation to five loops in a massless Abelian Higgs model using RGE, incorporating multi-scale effects and higher loop information.

Findings

Evidence of a rich vacuum structure depending on gauge coupling and scalar number.

Demonstration of effective potential calculation up to five loops.

Insights into dynamical symmetry breaking in the model.

Abstract

In this paper, we investigate the application of the Renormalization Group Equation (RGE) in the determination of the effective potential and the study of Dynamical Symmetry Breaking (DSB) in a massless Abelian Higgs (AH) model with an N-component complex scalar field in (3+1) dimensional spacetime. The classical Lagrangian of this model has scale invariance, which can be broken by radiative corrections to the effective potential. It is possible to calculate the effective potential using the RGE and the renormalization group functions that are obtained directly from loop calculations of the model and, using the leading logs approximation, information about higher loop orders can be included in the effective potential thus obtained. To show this, we use the renormalization group functions reported in the literature, obtained with a four loop calculation, and obtain a five loop approximation to the effective potential, in doing so, we have to properly take into account the fact that the model has multiple scales, and convert the functions that were originally calculated in the minimal subtraction (MS) renormalization scheme to another scheme which is adequate for the RGE method. This result is then used to study the DSB, and we present evidence for a rich structure of classical vacua, depending on the value of gauge coupling constant and number of scalar fields, which are considered as free parameters.