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Conductivity and Permittivity in Plasma with nonequilibrium Electron Distribution Function. / Li, Jinming; Getmanov, Igor; Kudryavtsev , Anatoliy A. ; Yuan, Chengxun; Wang, Xiaoou; Zhongxiang, Zhou.

In: IEEE Transactions on Plasma Science, 24.12.2019.

Research output: Contribution to journalArticlepeer-review

Harvard

Li, J, Getmanov, I, Kudryavtsev , AA, Yuan, C, Wang, X & Zhongxiang, Z 2019, 'Conductivity and Permittivity in Plasma with nonequilibrium Electron Distribution Function', IEEE Transactions on Plasma Science.

APA

Li, J., Getmanov, I., Kudryavtsev , A. A., Yuan, C., Wang, X., & Zhongxiang, Z. (2019). Conductivity and Permittivity in Plasma with nonequilibrium Electron Distribution Function. IEEE Transactions on Plasma Science.

Vancouver

Li J, Getmanov I, Kudryavtsev AA, Yuan C, Wang X, Zhongxiang Z. Conductivity and Permittivity in Plasma with nonequilibrium Electron Distribution Function. IEEE Transactions on Plasma Science. 2019 Dec 24.

Author

Li, Jinming ; Getmanov, Igor ; Kudryavtsev , Anatoliy A. ; Yuan, Chengxun ; Wang, Xiaoou ; Zhongxiang, Zhou. / Conductivity and Permittivity in Plasma with nonequilibrium Electron Distribution Function. In: IEEE Transactions on Plasma Science. 2019.

BibTeX

@article{2a97a94b6c6b4da59dfb2bfca3083ed3,
title = "Conductivity and Permittivity in Plasma with nonequilibrium Electron Distribution Function",
abstract = "Electron conductivity and dielectric permittivity are essential parameters that determine the external characteristics of laboratory and space plasmas in terms of electromagnetic (EM) wave propagation. In most problems, σ and ϵ are calculated using the elementary theory under the assumption that the electron distribution function (EDF) is under equilibrium (Maxwellian). But, in real plasma, the EDF is, as a rule, non-Maxwellian. Therefore, the form of EDF can significantly affect the characteristics of various processes involving electrons. In this article, the calculations of the correction coefficients for conductivity and permittivity in argon were performed in a wide frequency range for typical two-temperature EDFs, with which almost any EDF in the laboratory and ionospheric plasma can be approximated. The results show that the form of EDF has a significant effect on the conductivity and the permittivity in plasma. Most substantial differences are observed under conditions when the frequency of the EM wave is less than the transport electron-gas collision frequency of electrons.",
keywords = "dielectric permittivity, electron conductivity, non-Maxwellian electron distribution function (EDF).",
author = "Jinming Li and Igor Getmanov and Kudryavtsev, {Anatoliy A.} and Chengxun Yuan and Xiaoou Wang and Zhou Zhongxiang",
year = "2019",
month = dec,
day = "24",
language = "English",
journal = "IEEE Transactions on Plasma Science",
issn = "0093-3813",
publisher = "Institute of Electrical and Electronics Engineers Inc.",

}

RIS

TY - JOUR

T1 - Conductivity and Permittivity in Plasma with nonequilibrium Electron Distribution Function

AU - Li, Jinming

AU - Getmanov, Igor

AU - Kudryavtsev , Anatoliy A.

AU - Yuan, Chengxun

AU - Wang, Xiaoou

AU - Zhongxiang, Zhou

PY - 2019/12/24

Y1 - 2019/12/24

N2 - Electron conductivity and dielectric permittivity are essential parameters that determine the external characteristics of laboratory and space plasmas in terms of electromagnetic (EM) wave propagation. In most problems, σ and ϵ are calculated using the elementary theory under the assumption that the electron distribution function (EDF) is under equilibrium (Maxwellian). But, in real plasma, the EDF is, as a rule, non-Maxwellian. Therefore, the form of EDF can significantly affect the characteristics of various processes involving electrons. In this article, the calculations of the correction coefficients for conductivity and permittivity in argon were performed in a wide frequency range for typical two-temperature EDFs, with which almost any EDF in the laboratory and ionospheric plasma can be approximated. The results show that the form of EDF has a significant effect on the conductivity and the permittivity in plasma. Most substantial differences are observed under conditions when the frequency of the EM wave is less than the transport electron-gas collision frequency of electrons.

AB - Electron conductivity and dielectric permittivity are essential parameters that determine the external characteristics of laboratory and space plasmas in terms of electromagnetic (EM) wave propagation. In most problems, σ and ϵ are calculated using the elementary theory under the assumption that the electron distribution function (EDF) is under equilibrium (Maxwellian). But, in real plasma, the EDF is, as a rule, non-Maxwellian. Therefore, the form of EDF can significantly affect the characteristics of various processes involving electrons. In this article, the calculations of the correction coefficients for conductivity and permittivity in argon were performed in a wide frequency range for typical two-temperature EDFs, with which almost any EDF in the laboratory and ionospheric plasma can be approximated. The results show that the form of EDF has a significant effect on the conductivity and the permittivity in plasma. Most substantial differences are observed under conditions when the frequency of the EM wave is less than the transport electron-gas collision frequency of electrons.

KW - dielectric permittivity

KW - electron conductivity

KW - non-Maxwellian electron distribution function (EDF).

UR - https://ieeexplore.ieee.org/stamp/stamp.jsp?arnumber=8941105

UR - https://ieeexplore.ieee.org/search/searchresult.jsp?newsearch=true&queryText=Conductivity%20and%20Permittivity%20in%20Plasma%20with%20nonequilibrium%20Electron%20Distribution%20Function

M3 - Article

JO - IEEE Transactions on Plasma Science

JF - IEEE Transactions on Plasma Science

SN - 0093-3813

ER -

ID: 48790661