Reconciling ionization energies and band gaps of warm dense matter derived with ab initio simulations and average atom models

Average atom (AA) models allow one to efficiently compute electronic and optical properties of materials over a wide range of conditions and are often employed to interpret experimental data. However, at high pressure, predictions from AA models have been shown to disagree with results from ab initi...

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Veröffentlicht in:	arXiv.org 2021-05
Hauptverfasser:	Massacrier, G, Böhme, M, Vorberger, J, Soubiran, F, Militzer, B
Format:	Artikel
Sprache:	eng
Schlagworte:	Aluminum Boundary conditions Eigenvectors Material properties Optical properties Physics - Plasma Physics Simulation
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description	Average atom (AA) models allow one to efficiently compute electronic and optical properties of materials over a wide range of conditions and are often employed to interpret experimental data. However, at high pressure, predictions from AA models have been shown to disagree with results from ab initio computer simulations. Here we reconcile these deviations by developing an innovative type of AA model, AVION, that computes the electronic eigenstates with novel boundary conditions within the ion sphere. Bound and free states are derived consistently. We drop the common AA image that the free-particle spectrum starts at the potential threshold, which we found to be incompatible with ab initio calculations. We perform ab initio simulations of crystalline and liquid carbon and aluminum over a wide range of densities and show that the computed band structure is in very good agreement with predictions from AVION.
doi_str_mv	10.48550/arxiv.2105.01927
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subjects	Aluminum Boundary conditions Eigenvectors Material properties Optical properties Physics - Plasma Physics Simulation
title	Reconciling ionization energies and band gaps of warm dense matter derived with ab initio simulations and average atom models
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