Liquid-gas phase transition of nuclear matter

TL;DR

This paper reviews empirical evidence and theoretical models of the first-order liquid-gas phase transition in nuclear matter, discussing critical points, equations of state, and implications from chiral effective field theory.

Contribution

It provides a comprehensive survey combining experimental data, phenomenological models, and advanced theoretical approaches to understand the nuclear liquid-gas phase transition.

Findings

Identification of critical temperature and pressure from multifragmentation data

Application of Van der Waals analogy to nuclear potentials

Discussion of chiral effective field theory implications

Abstract

A survey is presented summarizing the empirical evidence for and interpretations of a first-order liquid-gas phase transition in nuclear matter. Earlier developments and the present state of knowledge about the extraction of the critical point for such a transition, primarily from the systematics of multifragmention data, are outlined. By analogy with a Van der Waals equation of state, the empirically deduced critical temperature and pressure permit to draw a schematic picture of the underlying nuclear potential. More detailed approaches to the liquid-gas transition using self-consistent nuclear Hartree-Fock and variational calculations are described. Critical exponents are reported. Then chiral effective field theory, as the low-energy realization of QCD, is discussed in the context of nuclear thermodynamics. Its implications for the liquid-gas transition in symmetric nuclear matter as well as in neutron-rich matter are reviewed.