Conserving approximations to dilute equilibrium systems. Pair interaction potential

TL;DR

This paper investigates self-consistent approximations for dilute strongly interacting fermionic systems, analyzing spectral functions, conservation laws, virial coefficients, and equations of state with applications to nuclear and classical potentials.

Contribution

It provides a comprehensive analysis of $ ext{Phi}$-derivable and virial approaches, deriving virial coefficients, and examining their application to nuclear and classical potentials in dilute equilibrium systems.

Findings

Exact conservation of fermion number densities in $ ext{Phi}$-derivable schemes.

Derived expressions for second and third virial coefficients for specific potentials.

Analyzed the impact of nucleon-nucleon scattering length and Pauli blocking on the virial equation of state.

Abstract

We study self-consistent approximations such as the $\Phi$-derivable and virial approaches to dilute strongly interacting systems in equilibrium. We consider a system of non-relativistic fermions of one kind interacting via a pair potential Thermodynamical quantities are expressed in terms of various spectral functions. We review the $\Phi$ derivable approximation scheme demonstrating the exact conservation of the Noether and the Botermans-Malfliet fermion number densities, and then for $\Phi$ described by the tadpole and sandwich diagrams we show the coincidence of these two number densities. As examples of test pair potentials, we consider the Yukawa central nucleon-nucleon potentials within Walecka, CD Bonn, and Reid parameterizations, and the corresponding classical Lennard-Jones potentials. Expressions for the second and third virial coefficients are derived and analyzed for $\Phi$ described by the tadpole and sandwich diagrams. Next, we focus on the virial approach to the equation of state. Classical, semiclassical, and purely quantum approaches are studied in detail. Then, different extrapolations of the virial equation of state are considered including the van~der~Waals form and excluded-volume models. We derive the expression for the second virial coefficient using the effective range approximation for the scattering amplitude and compare the result with the purely quantum result using the experimental phase shifts. Attention is focused on the problem of anomalously large value of the nucleon-nucleon scattering length appearing due to the presence of the quasi-bound state in nucleon-nucleon scattering, which can be destroyed in the matter because of the action of the Pauli blocking. We present results for the second virial coefficient subtracting this term. We discuss the validity of such a procedure to describe the equation of state of the nuclear matter in the virial limit.