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Computer simulation of corona discharge in an inert gas. / Stishkov, Yu K.; Samusenko, A. V.

In: Surface Engineering and Applied Electrochemistry, Vol. 44, No. 4, 19.09.2008, p. 271-280.

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Harvard

Stishkov, YK & Samusenko, AV 2008, 'Computer simulation of corona discharge in an inert gas', Surface Engineering and Applied Electrochemistry, vol. 44, no. 4, pp. 271-280. https://doi.org/10.3103/S1068375508040042

APA

Vancouver

Stishkov YK, Samusenko AV. Computer simulation of corona discharge in an inert gas. Surface Engineering and Applied Electrochemistry. 2008 Sep 19;44(4):271-280. https://doi.org/10.3103/S1068375508040042

Author

Stishkov, Yu K. ; Samusenko, A. V. / Computer simulation of corona discharge in an inert gas. In: Surface Engineering and Applied Electrochemistry. 2008 ; Vol. 44, No. 4. pp. 271-280.

BibTeX

@article{26e9c9d3d5dc4c7f868d7e5b20f9beaf,
title = "Computer simulation of corona discharge in an inert gas",
abstract = "In this document, computation of the corona discharge in a {"}cylinder-cylinder{"} electrode system is described. The Fokker-Planck equation is used to describe the kinetics of the electrons. The basic features of the physical process were observed in the solution. It shows that the stationary mode is possible only when the voltage is larger than a definite threshold value. One can discern two character areas between the electrodes. The internal area where the ionization is active and the current is carried both by electrons and ions has radius of 100-200 micrometers. The rest of the accommodation constitutes the drift area. The solution enables one to compare the illuminating zone and the zone of electrons multiplication. It revealed some features of rare gas discharge that preclude from directly applying the results of this work to discharge in air. Above all, it is a small value of negative charge density, which is caused by the electron conduction character in the external area. Nevertheless the solution of this model problem displays the wide possibilities of the method.",
author = "Stishkov, {Yu K.} and Samusenko, {A. V.}",
year = "2008",
month = sep,
day = "19",
doi = "10.3103/S1068375508040042",
language = "English",
volume = "44",
pages = "271--280",
journal = "Surface Engineering and Applied Electrochemistry",
issn = "1068-3755",
publisher = "Allerton Press, Inc.",
number = "4",

}

RIS

TY - JOUR

T1 - Computer simulation of corona discharge in an inert gas

AU - Stishkov, Yu K.

AU - Samusenko, A. V.

PY - 2008/9/19

Y1 - 2008/9/19

N2 - In this document, computation of the corona discharge in a "cylinder-cylinder" electrode system is described. The Fokker-Planck equation is used to describe the kinetics of the electrons. The basic features of the physical process were observed in the solution. It shows that the stationary mode is possible only when the voltage is larger than a definite threshold value. One can discern two character areas between the electrodes. The internal area where the ionization is active and the current is carried both by electrons and ions has radius of 100-200 micrometers. The rest of the accommodation constitutes the drift area. The solution enables one to compare the illuminating zone and the zone of electrons multiplication. It revealed some features of rare gas discharge that preclude from directly applying the results of this work to discharge in air. Above all, it is a small value of negative charge density, which is caused by the electron conduction character in the external area. Nevertheless the solution of this model problem displays the wide possibilities of the method.

AB - In this document, computation of the corona discharge in a "cylinder-cylinder" electrode system is described. The Fokker-Planck equation is used to describe the kinetics of the electrons. The basic features of the physical process were observed in the solution. It shows that the stationary mode is possible only when the voltage is larger than a definite threshold value. One can discern two character areas between the electrodes. The internal area where the ionization is active and the current is carried both by electrons and ions has radius of 100-200 micrometers. The rest of the accommodation constitutes the drift area. The solution enables one to compare the illuminating zone and the zone of electrons multiplication. It revealed some features of rare gas discharge that preclude from directly applying the results of this work to discharge in air. Above all, it is a small value of negative charge density, which is caused by the electron conduction character in the external area. Nevertheless the solution of this model problem displays the wide possibilities of the method.

UR - http://www.scopus.com/inward/record.url?scp=51749088144&partnerID=8YFLogxK

U2 - 10.3103/S1068375508040042

DO - 10.3103/S1068375508040042

M3 - Article

AN - SCOPUS:51749088144

VL - 44

SP - 271

EP - 280

JO - Surface Engineering and Applied Electrochemistry

JF - Surface Engineering and Applied Electrochemistry

SN - 1068-3755

IS - 4

ER -

ID: 36969587