An analysis of the hybrid finite-difference time-domain scheme for modeling the propagation of electromagnetic waves in cold magnetized toroidal plasma

Maryna Surkova; Yvan Pavlenko; Guido Van Oost; Dirk Van Eester; Daniël De Zutter

doi:10.1088/0031-8949/2014/T161/014014

An analysis of the hybrid finite-difference time-domain scheme for modeling the propagation of electromagnetic waves in cold magnetized toroidal plasma

Maryna Surkova, Yvan Pavlenko, Guido Van Oost, Dirk Van Eester, Daniël De Zutter

Laboratory for Plasma Physics

Research output: Contribution to journal › Conference article › peer-review

Abstract

To explore the behavior of electromagnetic waves in cold magnetized plasma, a three-dimensional cylindrical hybrid finite-difference time-domain model is developed. The full discrete dispersion relation is derived and compared with the exact solutions. We establish an analytical proof of stability in the case of nonmagnetized plasma. We demonstrate that in the case of nonmagnetized cold plasma the maximum stable Courant number of the hybrid method coincides with the vacuum Courant condition. In the case of magnetized plasma the stability of the applied numerical scheme is investigated by numerical simulation. In order to determine the utility of the applied difference scheme we complete the analysis of the numerical method demonstrating the limit of the reliability of the numerical results.

Original language	English
Article number	014014
Journal	Physica Scripta
Volume	T161
DOIs	https://doi.org/10.1088/0031-8949/2014/T161/014014
Publication status	Published - 2014
Event	International Conference on Research and Applications of Plasmas, PLASMA 2013 - Warsaw, Poland Duration: 2 Sept 2013 → 6 Sept 2013

Keywords

FDTD method
discrete dispersion relation
magnetized plasma

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10.1088/0031-8949/2014/T161/014014

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title = "An analysis of the hybrid finite-difference time-domain scheme for modeling the propagation of electromagnetic waves in cold magnetized toroidal plasma",

abstract = "To explore the behavior of electromagnetic waves in cold magnetized plasma, a three-dimensional cylindrical hybrid finite-difference time-domain model is developed. The full discrete dispersion relation is derived and compared with the exact solutions. We establish an analytical proof of stability in the case of nonmagnetized plasma. We demonstrate that in the case of nonmagnetized cold plasma the maximum stable Courant number of the hybrid method coincides with the vacuum Courant condition. In the case of magnetized plasma the stability of the applied numerical scheme is investigated by numerical simulation. In order to determine the utility of the applied difference scheme we complete the analysis of the numerical method demonstrating the limit of the reliability of the numerical results.",

keywords = "FDTD method, discrete dispersion relation, magnetized plasma",

author = "Maryna Surkova and Yvan Pavlenko and \{Van Oost\}, Guido and \{Van Eester\}, Dirk and \{De Zutter\}, Dani{\"e}l",

year = "2014",

doi = "10.1088/0031-8949/2014/T161/014014",

language = "English",

volume = "T161",

journal = "Physica Scripta",

issn = "0281-1847",

note = "International Conference on Research and Applications of Plasmas, PLASMA 2013 ; Conference date: 02-09-2013 Through 06-09-2013",

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TY - JOUR

T1 - An analysis of the hybrid finite-difference time-domain scheme for modeling the propagation of electromagnetic waves in cold magnetized toroidal plasma

AU - Surkova, Maryna

AU - Pavlenko, Yvan

AU - Van Oost, Guido

AU - Van Eester, Dirk

AU - De Zutter, Daniël

PY - 2014

Y1 - 2014

N2 - To explore the behavior of electromagnetic waves in cold magnetized plasma, a three-dimensional cylindrical hybrid finite-difference time-domain model is developed. The full discrete dispersion relation is derived and compared with the exact solutions. We establish an analytical proof of stability in the case of nonmagnetized plasma. We demonstrate that in the case of nonmagnetized cold plasma the maximum stable Courant number of the hybrid method coincides with the vacuum Courant condition. In the case of magnetized plasma the stability of the applied numerical scheme is investigated by numerical simulation. In order to determine the utility of the applied difference scheme we complete the analysis of the numerical method demonstrating the limit of the reliability of the numerical results.

AB - To explore the behavior of electromagnetic waves in cold magnetized plasma, a three-dimensional cylindrical hybrid finite-difference time-domain model is developed. The full discrete dispersion relation is derived and compared with the exact solutions. We establish an analytical proof of stability in the case of nonmagnetized plasma. We demonstrate that in the case of nonmagnetized cold plasma the maximum stable Courant number of the hybrid method coincides with the vacuum Courant condition. In the case of magnetized plasma the stability of the applied numerical scheme is investigated by numerical simulation. In order to determine the utility of the applied difference scheme we complete the analysis of the numerical method demonstrating the limit of the reliability of the numerical results.

KW - FDTD method

KW - discrete dispersion relation

KW - magnetized plasma

UR - https://www.scopus.com/pages/publications/84901506608

U2 - 10.1088/0031-8949/2014/T161/014014

DO - 10.1088/0031-8949/2014/T161/014014

M3 - Conference article

AN - SCOPUS:84901506608

SN - 0281-1847

VL - T161

JO - Physica Scripta

JF - Physica Scripta

M1 - 014014

T2 - International Conference on Research and Applications of Plasmas, PLASMA 2013

Y2 - 2 September 2013 through 6 September 2013

ER -

An analysis of the hybrid finite-difference time-domain scheme for modeling the propagation of electromagnetic waves in cold magnetized toroidal plasma

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Keywords

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