Optical and transport properties of plasma mixtures from ab initio molecular dynamics

Alexander J. White; Galen T. Craven; Vidushi Sharma; Lee A. Collins

doi:10.1063/5.0198003

Optical and transport properties of plasma mixtures from ab initio molecular dynamics

Alexander J. White, Galen T. Craven, Vidushi Sharma, Lee A. Collins

Research output: Contribution to journal › Article › peer-review

5 Scopus citations

Abstract

Predicting the charged particle transport properties of warm dense matter/hot dense plasma mixtures is a challenge for analytical models. High accuracy ab initio methods are more computationally expensive, but can provide critical insight by explicitly simulating mixtures. In this work, we investigate the transport properties and optical response of warm dense carbon-hydrogen mixtures at varying concentrations under either conserved electronic pressure or mass density at a constant temperature. We compare options for mixing the calculated pure species properties to estimate the results of the mixtures. We find that a combination of the Drude model with the Matthiessen's rule works well for DC electron transport and low-frequency optical response. This breaks down at higher frequencies, where a volumetric mix of pure-species AC conductivities works better.

Original language	English (US)
Article number	042706
Journal	Physics of Plasmas
Volume	31
Issue number	4
DOIs	https://doi.org/10.1063/5.0198003
State	Published - Apr 1 2024
Externally published	Yes

All Science Journal Classification (ASJC) codes

Condensed Matter Physics

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10.1063/5.0198003

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title = "Optical and transport properties of plasma mixtures from ab initio molecular dynamics",

abstract = "Predicting the charged particle transport properties of warm dense matter/hot dense plasma mixtures is a challenge for analytical models. High accuracy ab initio methods are more computationally expensive, but can provide critical insight by explicitly simulating mixtures. In this work, we investigate the transport properties and optical response of warm dense carbon-hydrogen mixtures at varying concentrations under either conserved electronic pressure or mass density at a constant temperature. We compare options for mixing the calculated pure species properties to estimate the results of the mixtures. We find that a combination of the Drude model with the Matthiessen's rule works well for DC electron transport and low-frequency optical response. This breaks down at higher frequencies, where a volumetric mix of pure-species AC conductivities works better.",

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AU - White, Alexander J.

AU - Craven, Galen T.

AU - Sharma, Vidushi

AU - Collins, Lee A.

PY - 2024/4/1

Y1 - 2024/4/1

N2 - Predicting the charged particle transport properties of warm dense matter/hot dense plasma mixtures is a challenge for analytical models. High accuracy ab initio methods are more computationally expensive, but can provide critical insight by explicitly simulating mixtures. In this work, we investigate the transport properties and optical response of warm dense carbon-hydrogen mixtures at varying concentrations under either conserved electronic pressure or mass density at a constant temperature. We compare options for mixing the calculated pure species properties to estimate the results of the mixtures. We find that a combination of the Drude model with the Matthiessen's rule works well for DC electron transport and low-frequency optical response. This breaks down at higher frequencies, where a volumetric mix of pure-species AC conductivities works better.

AB - Predicting the charged particle transport properties of warm dense matter/hot dense plasma mixtures is a challenge for analytical models. High accuracy ab initio methods are more computationally expensive, but can provide critical insight by explicitly simulating mixtures. In this work, we investigate the transport properties and optical response of warm dense carbon-hydrogen mixtures at varying concentrations under either conserved electronic pressure or mass density at a constant temperature. We compare options for mixing the calculated pure species properties to estimate the results of the mixtures. We find that a combination of the Drude model with the Matthiessen's rule works well for DC electron transport and low-frequency optical response. This breaks down at higher frequencies, where a volumetric mix of pure-species AC conductivities works better.

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JF - Physics of Plasmas

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ER -

Optical and transport properties of plasma mixtures from ab initio molecular dynamics

Abstract

All Science Journal Classification (ASJC) codes

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