Atoms in Dense Plasmas: Models, Applications, and Current Challenges

TL;DR

This paper discusses the modeling of dense plasmas using atomic and ionic models, highlighting their applications, current challenges, and the author's contributions to the field of non-ideal plasma atomic modeling.

Contribution

The paper presents recent advances in atomic modeling of dense, non-ideal plasmas and explores the integration of collisional-radiative models with dense plasma models.

Findings

Atomic models extend atomic physics tools to dense plasmas.

Collisional-radiative modeling aids in understanding non-equilibrium plasmas.

Bridging dense plasma and non-LTE models offers new research avenues.

Abstract

Modeling plasmas in terms of atoms or ions is theoretically appealing for several reasons. When it is relevant, the notion of atom or ion in a plasma provides us with an interpretation scheme of the plasma's microscopic structure. From the standpoint of quantitative estimation of plasma properties, atomic models of plasma allow extending many theoretical tools of atomic physics to plasmas. This notably includes the statistical approaches to the detailed accounting for excited states, or the collisional-radiative modeling of non-equilibrium plasmas, which is based on the notion of atomic processes. This habilitation thesis is mostly focused on the studies to which the author has contributed in the field of atomic modeling of dense, non-ideal plasmas. The studies to which the author contributed in the field of collisional-radiative modeling of non-LTE plasmas are also addressed, and the prospect of bridging with dense-plasma models is sketched.