Effective Potential of O(N) Linear Sigma Model at Finite Temperature

TL;DR

This paper investigates the O(N) linear sigma model at finite temperature, demonstrating that the Nambu-Goldstone theorem holds without large N approximation when using a symmetry-conserving propagator and a new renormalization scheme.

Contribution

It introduces a novel renormalization prescription and confirms the massless nature of pions below the critical temperature without relying on large N limit.

Findings

Pions remain massless below the critical temperature.

A new renormalization scheme for the CJT effective potential is proposed.

Discussion on the phase transition order and sigma meson mass issues.

Abstract

We study the O(N) symmetric linear sigma model at finite temperature as the low-energy effective models of quantum chromodynamics(QCD) using the Cornwall-Jackiw-Tomboulis(CJT) effective action for composite operators. It has so far been claimed that the Nambu-Goldstone theorem is not satisfied at finite temperature in this framework unless the large N limit in the O(N) symmetry is taken. We show that this is not the case. The pion is always massless below the critical temperature, if one determines the propagator within the form such that the symmetry of the system is conserved, and defines the pion mass as the curvature of the effective potential. We use a new renormalization prescription for the CJT effective potential in the Hartree-Fock approximation. A numerical study of the Schwinger-Dyson equation and the gap equation is carried out including the thermal and quantum loops. We point out a problem in the derivation of the sigma meson mass without quantum correction at finite temperature. A problem about the order of the phase transition in this approach is also discussed.