Supercomputer Modeling of Generation of Electromagnetic Radiation by Beam–Plasma Interaction

Berendeev E.; Boronina M.; Dudnikova G.; Efimova A.; Vshivkov V.

doi:10.1007/978-3-319-67035-5_18

Инд. авторы:	Berendeev E., Boronina M., Dudnikova G., Efimova A., Vshivkov V.
Заглавие:	Supercomputer Modeling of Generation of Electromagnetic Radiation by Beam–Plasma Interaction
Библ. ссылка:	Berendeev E., Boronina M., Dudnikova G., Efimova A., Vshivkov V. Supercomputer Modeling of Generation of Electromagnetic Radiation by Beam–Plasma Interaction // Communications in Computer and Information Science. - 2017. - Vol.753. - P.247-260. - ISSN 1865-0929. - EISSN 1865-0937.
Внешние системы:	DOI: 10.1007/978-3-319-67035-5_18; SCOPUS: 2-s2.0-85032512734; РИНЦ: 31071536;
Реферат:	eng: We construct in this article a two-dimensional particle-in- cell (PIC) numerical model of electron beam - plasma interaction based on the kinetic description of both ion and electron components with a continuously injected electron beam, and develop the corresponding parallel code. In this model, an electron beam, entering the plasma along magnetic field lines through one boundary and leaving it through the other, provides a continuous pumping of plasma oscillations. Such a problem statement requires that the model be constructed in a sufficiently long plasma region, where the time is long enough for the beam to be captured by the exciting wave field. The parallel algorithm was successfully applied to the solution of resource-intensive problem by efficiently using large numbers of computational cores. © 2017, Springer International Publishing AG.
Ключевые слова:	Generation of electromagnetic radiation; Electron beam pumping; Problem statement; Particle in cell method; Open plasma trap; Magnetic field line; Kinetic description; Injected electron beams; Electron component; Computational core; Vlasov equation; Plasma oscillations; Plasma interactions; Maxwell equations; Electrons; Electron beams; Electromagnetic waves; Electromagnetic wave emission; Computational efficiency; Beam plasma interactions; Vlasov equation; Particle-in-cell methods; Open plasma trap; Supercomputers; Maxwell’s equations;
Издано:	2017
Физ. характеристика:	с.247-260
Конференция:	Название: 11th International Conference on Parallel Computational Technologies Аббревиатура: PCT 2017 Город: Kazan Страна: Russia Даты проведения: 2017-04-03 - 2017-04-07
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