The effective potential of N-vector models: a field-theoretic study to O(\epsilon^3)

TL;DR

This paper computes the small-field expansion coefficients of the effective potential for three-dimensional O(N) models using a three-loop field-theoretic epsilon-expansion, providing new estimates for renormalized coupling constants.

Contribution

It presents the first three-loop calculations of the effective potential's coefficients for generic N in three-dimensional O(N) models using epsilon-expansion techniques.

Findings

Calculated $g_{2j}$ to three loops for various N

Provided estimates for renormalized coupling ratios $r_{2j}$

Used constrained analysis incorporating exact low-dimensional results

Abstract

We study the effective potential of three-dimensional O($N$) models. In statistical physics the effective potential represents the free-energy density as a function of the order parameter (Helmholtz free energy), and, therefore, it is related to the equation of state. In particular, we consider its small-field expansion in the symmetric (high-temperature) phase, whose coefficients are related to the zero-momentum $2j$-point renormalized coupling constants $g_{2j}$. For generic values of $N$, we calculate $g_{2j}$ to three loops in the field-theoretic approach based on the $\epsilon$-expansion. The estimates of $g_{2j}$, or equivalently of $r_{2j}\equiv g_{2j}/g_4^{j-1}$, are obtained by a constrained analysis of the series that takes into account the exact results in one and zero dimensions.