Approximating the nonlinear density dependence of electron transport coefficients and scattering rates across the gas-liquid interface

N. A. Garland; G. J. Boyle; D. G. Cocks; R. D. White

doi:10.1088/1361-6595/aaaa0c

Approximating the nonlinear density dependence of electron transport coefficients and scattering rates across the gas-liquid interface

N. A. Garland, G. J. Boyle, D. G. Cocks, R. D. White

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

8 Citations (Scopus)

Abstract

This study reviews the neutral density dependence of electron transport in gases and liquids and develops a method to determine the nonlinear medium density dependence of electron transport coefficients and scattering rates required for modeling transport in the vicinity of gas-liquid interfaces. The method has its foundations in Blanc's law for gas-mixtures and adapts the theory of Garland et al (2017 Plasma Sources Sci. Technol. 26) to extract electron transport data across the gas-liquid transition region using known data from the gas and liquid phases only. The method is systematically benchmarked against multi-term Boltzmann equation solutions for Percus-Yevick model liquids. Application to atomic liquids highlights the utility and accuracy of the derived method.

Original language	English
Article number	024002
Journal	Plasma Sources Science and Technology
Volume	27
Issue number	2
DOIs	https://doi.org/10.1088/1361-6595/aaaa0c
Publication status	Published - 14 Feb 2018

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title = "Approximating the nonlinear density dependence of electron transport coefficients and scattering rates across the gas-liquid interface",

abstract = "This study reviews the neutral density dependence of electron transport in gases and liquids and develops a method to determine the nonlinear medium density dependence of electron transport coefficients and scattering rates required for modeling transport in the vicinity of gas-liquid interfaces. The method has its foundations in Blanc's law for gas-mixtures and adapts the theory of Garland et al (2017 Plasma Sources Sci. Technol. 26) to extract electron transport data across the gas-liquid transition region using known data from the gas and liquid phases only. The method is systematically benchmarked against multi-term Boltzmann equation solutions for Percus-Yevick model liquids. Application to atomic liquids highlights the utility and accuracy of the derived method.",

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T1 - Approximating the nonlinear density dependence of electron transport coefficients and scattering rates across the gas-liquid interface

AU - Garland, N. A.

AU - Boyle, G. J.

AU - Cocks, D. G.

AU - White, R. D.

PY - 2018/2/14

Y1 - 2018/2/14

N2 - This study reviews the neutral density dependence of electron transport in gases and liquids and develops a method to determine the nonlinear medium density dependence of electron transport coefficients and scattering rates required for modeling transport in the vicinity of gas-liquid interfaces. The method has its foundations in Blanc's law for gas-mixtures and adapts the theory of Garland et al (2017 Plasma Sources Sci. Technol. 26) to extract electron transport data across the gas-liquid transition region using known data from the gas and liquid phases only. The method is systematically benchmarked against multi-term Boltzmann equation solutions for Percus-Yevick model liquids. Application to atomic liquids highlights the utility and accuracy of the derived method.

AB - This study reviews the neutral density dependence of electron transport in gases and liquids and develops a method to determine the nonlinear medium density dependence of electron transport coefficients and scattering rates required for modeling transport in the vicinity of gas-liquid interfaces. The method has its foundations in Blanc's law for gas-mixtures and adapts the theory of Garland et al (2017 Plasma Sources Sci. Technol. 26) to extract electron transport data across the gas-liquid transition region using known data from the gas and liquid phases only. The method is systematically benchmarked against multi-term Boltzmann equation solutions for Percus-Yevick model liquids. Application to atomic liquids highlights the utility and accuracy of the derived method.

KW - common mean energy

KW - electron transport

KW - fluid model

KW - interface

KW - momentum transfer theory

KW - plasma-liquid

KW - structured media

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DO - 10.1088/1361-6595/aaaa0c

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VL - 27

JO - Plasma Sources Science and Technology

JF - Plasma Sources Science and Technology

IS - 2

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ER -

Approximating the nonlinear density dependence of electron transport coefficients and scattering rates across the gas-liquid interface

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