Structural characteristics of strongly coupled ions in a dense quantum plasma

TL;DR

This paper investigates the structural properties of strongly coupled ions in dense quantum plasmas, emphasizing the role of electronic screening approximations and their impact on ion correlations and structure factors.

Contribution

It compares different screening models, including STLS and quantum Monte Carlo data, to assess their effects on ion structural properties in dense plasmas.

Findings

Screened pair interaction potential significantly influences structural properties.

STLS approximation's applicability depends on electron density and temperature.

Electronic correlations beyond RPA are important for rs > 1.

Abstract

The structural properties of strongly coupled ions in dense plasmas with moderately to strongly degenerate electrons are investigated in the framework of the one-component plasma model of ions interacting through a screened pair interaction potential. Special focus is put on the description of the electronic screening in the Singwi-Tosi-Land-Sjoelander (STLS) approximation. Different crosschecks and analyses using ion potentials obtained from ground-state quantum Monte Carlo data, the random phase approximation (RPA), and existing analytical models are presented for the computation of the structural properties, such as the pair distribution and the static structure factor, of strongly coupled ions. The results are highly sensitive to the features of the screened pair interaction potential. This effect is particularly visible in the static structure factor. The applicability range of the screened potential computed from STLS is identified in terms of density and temperature of the electrons. It is demonstrated that at r_s > 1, where rs is the ratio of the mean inter-electronic distance to the Bohr radius, electronic correlations beyond RPA have a non-negligible effect on the structural properties. Additionally, the applicability of the hypernetted chain approximation for the calculation of the structural properties using the screened pair interaction potential is analyzed employing the effective coupling parameter approach.