2D fluid approaches of a DC normal glow discharge: current densities

• Autorzy: Bouchikhi A.

Identyfikatory

DOI

10.15199/48.2016.06.30

Warianty tytułu

PL

Model cieczy 2D do analizy wyładowania DC – gęstości prądów

• Języki publikacji: EN

Abstrakty

EN

In this manuscript, both electric and energy behavior of a 2D spatial distributions in the Cartesian geometry of electron, ion and total longitudinal current densities as well as both ionization and energy sources terms of a DC glow discharge in the normal mode and in low gas pressure are presented for the first time in the literature. The model used in this work is the second order fluid model (continuity and momentum transfer equations and energy equation for electrons). The set of equations are coupled in a self-consistent way with Poisson’s equation. The results obtained in the stationary state are in good agreement with those given by literature.

PL

Analizowany jest prąd wyładowania DC i określany jest przestrzenny rozkład strumienia elektronów, jonów, prądu a także pokreślone są źródła energii jonizacji. Jako model do analizy przyjęto model płynu drugiego rzędu. Równania są sprzężone z odpowiednimi równaniami Poissona.

Słowa kluczowe

EN

glow discharge; Boltzmann equation; Poisson's equation

PL

wyładowanie DC; równanie Boltzmanna; równanie Poissona

• Wydawca: Wydawnictwo SIGMA-NOT
• Czasopismo: Przegląd Elektrotechniczny
• Rocznik: 2016
• Tom: R. 92, nr 6
• Strony: 149--153
• Opis fizyczny: Bibliogr. 19 poz., rys., wykr.

Twórcy

autor

Bouchikhi A.

• University of Saïda, Faculty of the Technology, Department of the Electrical Engineering, 20000, Algeria

Bibliografia

• [1] Meyyappan M., Kreskovsky J. P., Glow discharge simulation through solutions to the moments of the Boltzmann transport equation, J. Appl. Phys., (68)1990, No. 4, 1506-1512
• [2] Bogaerts A., Gijbels R., Modeling of metastable argon atoms in a direct-current glow discharge, Phys. Rev. A., (52)1995, No. 5, 3743-3751
• [3] Bogaerts A., Gijbels R., Two-Dimensional Model of a Direct Current Glow Discharge: Description of the Argon Metastable Atoms, Sputtered Atoms, and Ions, Anal. Chem., 68(1996), No.15, 2676-2685
• [4] Schmitt W., Köhler W. E., Ruder H., A one-dimensional model of dc glow discharges, J. Appl. Phys., (71)1992, No. 12, 5783-5791
• [5] Belenguer Ph., Boeuf J. P., Transition between different regimes of rf glow discharges, Phys. Rev. A., (41)1990, No. 8, 4447-4459
• [6] Oh Y. H., Choi N. H., Choi D. I., A numerical simulation of rf glow discharge containing an electronegative gas composition, J. Appl. Phys., (67) 1990, No. 7, 3264-3268
• [7] Bouchikhi A., Hamid A., Through Solutions to the Moments of the Boltzmann Equation for DC Glow Discharge, IRPHY., (2) 2008, No. 4, 196-203
• [8] Bouchikhi A., Hamid A., One dimensional continuum model for dc glow discharge, International Conference on Electrical Systems Design and Technologies, Tunisia, 2008, www.iceedt.esgroups.org
• [9] Bouchikhi A., Modèle fluide d’ordre deux en 1D et 2D d’une décharge luminescente, Ph.D. University of Oran, Algeria, 2010
• [10] Bouchikhi A., Hamid A., 2D DC Subnormal Glow Discharge in Argon, Plasma Sci. Technol., (12)2010, No. 1, 59-66
• [11] Bouchikhi A., Two-dimensional numerical simulation of the DC glow discharge in the normal mode and with Einstein's relation of electron diffusivity, Plasma Sci. Technol., 14(2012), No. 11, 965-973
• [12] Marié D., Kutasi K., Malovié G., Donko Z., Petrovié Z. L., Axial emission profiles and apparent secondary electron yield in abnormal glow discharges in argon, Eur. Phys. J. D., 21(2002),73-81
• [13] Donko Z., Hybrid model of a rectangular hollow cathode discharge, Phys. Rev. E., 57(1998), No. 6, 7126-7137 [14] Lin Y. H., Adomaitis R. A., A global basis function approach to dc glow discharge simulation, Technical research report, T.R. 81, University of Maryland, USA, 1997
• [15] Lin Y. H., From detailed simulation to model reduction: development of numerical tools for a plasma processing application, Ph.D. Institute for Systems Research, University Maryland, USA, 1999, www.isr.umd.edu
• [16] Lin Y. H., Adomaitis R. A., A global basis function approach to dc glow discharge simulation, Physics. Letters. A., 243(1998), 142-150
• [17] Park S., Economou D. J., Analysis of low pressure rf glow discharges using a continuum model, J. Appl. Phys., 68(1990), No. 1, 3904-3915
• [18] Fiala A., Modélisation Numérique Bidimensionnelle d’une Décharge Luminescente à basse pression, Ph.D. University of Toulouse, France, 1995
• [19] Scharfetter D. L., H. K. Gummel, Large-signal analysis of a silicon Read diode oscillator, IEEE. Trans. Electron Devices., (16)1969, No. 1, 64-77

Uwagi

Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę.