Thermodynamic phases and mesonic fluctuations in a chiral nucleon-meson model

TL;DR

This paper extends a chiral nucleon-meson model with mesonic fluctuations using the functional renormalization group, accurately describing the nuclear liquid-gas transition without indicating a chiral phase transition up to twice nuclear saturation density.

Contribution

It introduces a systematic inclusion of mesonic fluctuations in a chiral nucleon-meson model via the functional renormalization group, aligning well with advanced chiral effective field theory calculations.

Findings

Accurately describes the nuclear liquid-gas phase transition.

Finds no evidence of a chiral first-order phase transition up to twice nuclear saturation density.

Analyzes fluctuations near the liquid-gas critical point with detailed chiral susceptibility studies.

Abstract

Studies of the QCD phase diagram must properly include nucleonic degrees of freedom and their thermodynamics in the range of baryon chemical potentials characteristic of nuclear matter. A useful framework for incorporating relevant nuclear physics constraints in this context is a chiral nucleon-meson effective Lagrangian. In the present paper, such a chiral nucleon-meson model is extended with systematic inclusion of mesonic fluctuations using the functional renormalization group approach. The resulting description of the nuclear liquid-gas phase transition shows a remarkable agreement with three-loop calculations based on in-medium chiral effective field theory. No signs of a chiral first-order phase transition and its critical endpoint are found in the region of applicability of the model, at least up to twice the density of normal nuclear matter and at temperatures T<100 MeV. Fluctuations close to the critical point of the first-order liquid-gas transition are also examined with a detailed study of the chiral susceptibility.