Litcius/Paper detail

Ab initio results for the plasmon dispersion and damping of the warm dense electron gas

Paul Hamann, Jan Vorberger, Tobias Dornheim, Zhandos A. Moldabekov, M. Bönitz

2020Contributions to Plasma Physics54 citationsDOIOpen Access PDF

Abstract

Abstract Warm dense matter (WDM) is an exotic state on the border between condensed matter and dense plasmas. Important occurrences of WDM include dense astrophysical objects, matter in the core of our Earth, and matter produced in strong compression experiments. As of late, x‐ray Thomson scattering has become an advanced tool to diagnose WDM. The interpretation of the data requires model input for the dynamic structure factor S ( q , ω ) and the plasmon dispersion ω ( q ) . Recently, the first ab initio results for S ( q , ω ) of the homogeneous warm dense electron gas were obtained from path integral Monte Carlo simulations (Dornheim et al., Phys. Rev. Lett. , 121, 255001, 2018). Here, we analyse the effects of correlations and finite temperature on the dynamic dielectric function and the plasmon dispersion. Our results for the plasmon dispersion and damping differ significantly from the random‐phase approximation and from earlier models of the correlated electron gas. Moreover, we show when commonly used weak damping approximations break down and how the method of complex zeroes of the dielectric function can solve this problem for WDM conditions.

Topics & Concepts

Warm dense matterRandom phase approximationPlasmonPhysicsElectronAb initioComputational physicsQuasiparticleDispersion (optics)ScatteringCondensed matter physicsFermi gasPath integral Monte CarloMonte Carlo methodOpticsQuantum mechanicsPath integral formulationMathematicsSuperconductivityQuantumStatisticsQuantum, superfluid, helium dynamicsHigh-pressure geophysics and materialsIonosphere and magnetosphere dynamics