Litcius/Paper detail

First-principles derivation and properties of density-functional average-atom models

Timothy J. Callow, S. B. Hansen, Eli Kraisler, Attila Cangi

2022Physical Review Research17 citationsDOIOpen Access PDF

Abstract

Finite-temperature Kohn-Sham density functional theory (KS-DFT) is a widely-used method in warm dense matter (WDM) simulations and diagnostics. Unfortunately, full KS-DFT-molecular dynamics models scale unfavourably with temperature and there remains uncertainty regarding the performance of existing approximate exchange-correlation (XC) functionals under WDM conditions. Of particular concern is the expected explicit dependence of the XC functional on temperature, which is absent from most approximations. Average-atom (AA) models, which significantly reduce the computational cost of KS-DFT calculations, have therefore become an integral part of WDM modeling. In this paper, we present a derivation of a first-principles AA model from the fully-interacting many-body Hamiltonian, carefully analyzing the assumptions made and terms neglected in this reduction. We explore the impact of different choices within this model---such as boundary conditions and XC functionals---on common properties in WDM, for example equation-of-state data, ionization degree and the behavior of the frontier energy levels. Furthermore, drawing upon insights from ground-state KS-DFT, we discuss the likely sources of error in KS-AA models and possible strategies for mitigating such errors.

Topics & Concepts

Density functional theoryHamiltonian (control theory)Statistical physicsAtom (system on chip)Boundary value problemComputationApplied mathematicsPhysicsMathematicsComputer scienceQuantum mechanicsMathematical optimizationAlgorithmEmbedded systemHigh-pressure geophysics and materialsAdvanced Chemical Physics StudiesTheoretical and Computational Physics