Hanno Kählert

TL;DR: In this article, the electrostatic potential distribution around a dust grain in the presence of a streaming plasma environment is evaluated by means of two complementary approaches: (i) a high-precision computation of the dynamically screened Coulomb potential from the dynamic dielectric function and (ii) full 3D particle-in-cell simulations, which self-consistently include dynamical grain charging and nonlinear effects.

TL;DR: In this article, Dornheim et al. reviewed recent further progress in QMC simulations of the warm dense uniform electron gas (UEG) and provided ab initio results for the static local field correction G(q) and for the dynamic structure factor S ( q, ω ).

TL;DR: In this paper, Dornheim et al. reviewed recent further progress in QMC simulations of the warm dense uniform electron gas (UEG) that were obtained by quantum Monte Carlo (QMC) simulations, namely, \textit{ab initio} results for the static local field correction $G(q)$ and for the dynamic structure factor $S(q, \omega)$.

TL;DR: 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 and it is demonstrated that at r_{s}>1, where r is the ratio of the mean interelectronic distance to the Bohr radius, electronic correlations beyond RPA have a nonnegligible effect on the structural properties.

TL;DR: A concept is proposed that mimics the magnetization of the heavy dust particles in a complex plasma while leaving the properties of the light species practically unaffected and induces a Coriolis force that acts exactly as the Lorentz force in a magnetic field.