Geodesic
Simulations of ion and electron transport in low-temperature dusty plasma
Matematičeskoe modelirovanie, Tome 24 (2012) no. 7, pp. 13-32.

Voir la notice de l'article provenant de la source Math-Net.Ru

The efficient algorithm for numerical simulation of the charged particles transport in low-temperature dusty plasma is presented. The interaction of dust particles in plasma is a rather complex geometry, making it necessary to consider it within the two-dimensional geometry. The system of equations, which is used in a model, apart of transport equations include Poisson's equation. To solve the Poisson equation, the electric field potential was expanded in a series of Legendre polynomials.
Keywords: gas discharge, dusty plasma, numerical modeling. 
@article{MM_2012_24_7_a1,
     author = {Yu. V. Petrushevich},
     title = {Simulations of ion and electron transport in low-temperature dusty plasma},
     journal = {Matemati\v{c}eskoe modelirovanie},
     pages = {13--32},
     publisher = {mathdoc},
     volume = {24},
     number = {7},
     year = {2012},
     language = {ru},
     url = {http://geodesic.mathdoc.fr/item/MM_2012_24_7_a1/}
}
TY  - JOUR
AU  - Yu. V. Petrushevich
TI  - Simulations of ion and electron transport in low-temperature dusty plasma
JO  - Matematičeskoe modelirovanie
PY  - 2012
SP  - 13
EP  - 32
VL  - 24
IS  - 7
PB  - mathdoc
UR  - http://geodesic.mathdoc.fr/item/MM_2012_24_7_a1/
LA  - ru
ID  - MM_2012_24_7_a1
ER  - 
%0 Journal Article
%A Yu. V. Petrushevich
%T Simulations of ion and electron transport in low-temperature dusty plasma
%J Matematičeskoe modelirovanie
%D 2012
%P 13-32
%V 24
%N 7
%I mathdoc
%U http://geodesic.mathdoc.fr/item/MM_2012_24_7_a1/
%G ru
%F MM_2012_24_7_a1
Yu. V. Petrushevich. Simulations of ion and electron transport in low-temperature dusty plasma. Matematičeskoe modelirovanie, Tome 24 (2012) no. 7, pp. 13-32. http://geodesic.mathdoc.fr/item/MM_2012_24_7_a1/

[1] D'yachkov L. G., Khrapak A. G., Khrapak S. A., Morfill G. E., “Model of grain charging in collisional plasmas accounting for collisionless layer”, Physics of Plasmas, 14:4 (2007), 042102, 6 pp. | DOI

[2] Ratynskaia S., de Angelis U., Khrapak, S., Klumov B., Morfill G. E., “Electrostatic interaction between dust particles in weakly ionized complex plasmas”, Physics of Plasmas, 13:10 (2006), 104508 | DOI

[3] Vorob'ev V. S., Petrov O. F., Fortov V. E., “Self-consistent electric field inside ordered dust structures”, Physical Review E, 77 (2008), 036401 | DOI

[4] Vaulina O. S., “Modelirovanie dinamiki tsilindricheskikh pylevykh chastits vo vneshnem elektricheskom pole”, Fizika plazmy, 34:5 (2008), 453–462

[5] Stokes J. D. E., Samarian A. A., Vladimirov S. V., “Dynamics of two particles in a plasma sheath”, Physical Review E, 78 (2008), 036402 | DOI

[6] Petrushevich Yu. V., “Chislennoe modelirovanie perenosa ionov i elektronov v nizkotemperaturnoi plazme s kondensirovannoi dispersnoi fazoi”, Fizika plazmy, 29:6 (2003), 508–515

[7] Morfill G., Tsytovich V. N., Tomas Kh., “Kompleksnaya plazma. I: Elementarnye protsessy v kompleksnoi plazme”, Fizika plazmy, 29:1 (2003), 3–36

[8] Fortov V. E., Khrapak A. G., Khrapak S. A., Molotkov V. I., Petrov O. F., “Pylevaya plazma”, Uspekhi fizicheskikh nauk, 174 (2004), 495 | DOI

[9] Maiorov S. A., Ramazanov T. S., Dzhumagulova K. N., Jumabekov A. N., Dosbolayev M. K., “Investigation of plasma-dust structures in He-Ar gas mixture”, Physics of Plasmas, 15 (2008), 093701 | DOI

[10] Morfill G., Tsytovich V. N., Tomas Kh., “Kompleksnaya plazma. I: Kompleksnaya plazma, kak neobychnoe sostoyanie veschestva”, Fizika plazmy, 28:8 (2002), 675–707

[11] Khrapak S. A., Ivlev A. V., Morfill G. E., Thomas H. M., “Ion drag force in complex plasmas”, Physical Review E, 66 (2002), 046414 | DOI