3-D discrete dispersion relation, numerical stability, and accuracy of the hybrid FDTD model for cold magnetized toroidal plasma

Maryna Surkova; Wouter Tierens; Ivan Pavlenko; Dirk Van Eester; Guido Van Oost; Daniël De Zutter

doi:10.1109/TAP.2014.2361902

3-D discrete dispersion relation, numerical stability, and accuracy of the hybrid FDTD model for cold magnetized toroidal plasma

Maryna Surkova, Wouter Tierens, Ivan Pavlenko, Dirk Van Eester, Guido Van Oost, Daniël De Zutter

Laboratory for Plasma Physics

Onderzoeksoutput: Bijdrage aan een tijdschrift › Artikel › peer review

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The finite-difference time-domain (FDTD) method in cylindrical coordinates is used to describe electromagnetic wave propagation in a cold magnetized plasma. This enables us to study curvature effects in toroidal plasma. We derive the discrete dispersion relation of this FDTD scheme and compare it with the exact solution. The accuracy analysis of the proposed method is presented. We also provide a stability proof for nonmagnetized uniform plasma, in which case the stability condition is the vacuum Courant condition. For magnetized cold plasma we investigate the stability condition numerically using the von Neumann method. We present some numerical examples which reproduce the dispersion relation, wave field structure and steady state condition for typical plasma modes.

Originele taal-2	Engels
Artikelnummer	6918408
Pagina's (van-tot)	6307-6316
Aantal pagina's	10
Tijdschrift	IEEE Transactions on Antennas and Propagation
Volume	62
Nummer van het tijdschrift	12
DOI's	https://doi.org/10.1109/TAP.2014.2361902
Status	Gepubliceerd - 1 dec. 2014

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10.1109/TAP.2014.2361902

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title = "3-D discrete dispersion relation, numerical stability, and accuracy of the hybrid FDTD model for cold magnetized toroidal plasma",

abstract = "The finite-difference time-domain (FDTD) method in cylindrical coordinates is used to describe electromagnetic wave propagation in a cold magnetized plasma. This enables us to study curvature effects in toroidal plasma. We derive the discrete dispersion relation of this FDTD scheme and compare it with the exact solution. The accuracy analysis of the proposed method is presented. We also provide a stability proof for nonmagnetized uniform plasma, in which case the stability condition is the vacuum Courant condition. For magnetized cold plasma we investigate the stability condition numerically using the von Neumann method. We present some numerical examples which reproduce the dispersion relation, wave field structure and steady state condition for typical plasma modes.",

keywords = "Boundary conditions, Discretized dispersion relation, Finite-difference time-domain (FDTD) method, Magnetized plasma, Numerical stability",

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

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AU - Surkova, Maryna

AU - Tierens, Wouter

AU - Pavlenko, Ivan

AU - Van Eester, Dirk

AU - Van Oost, Guido

AU - De Zutter, Daniël

PY - 2014/12/1

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AB - The finite-difference time-domain (FDTD) method in cylindrical coordinates is used to describe electromagnetic wave propagation in a cold magnetized plasma. This enables us to study curvature effects in toroidal plasma. We derive the discrete dispersion relation of this FDTD scheme and compare it with the exact solution. The accuracy analysis of the proposed method is presented. We also provide a stability proof for nonmagnetized uniform plasma, in which case the stability condition is the vacuum Courant condition. For magnetized cold plasma we investigate the stability condition numerically using the von Neumann method. We present some numerical examples which reproduce the dispersion relation, wave field structure and steady state condition for typical plasma modes.

KW - Boundary conditions

KW - Discretized dispersion relation

KW - Finite-difference time-domain (FDTD) method

KW - Magnetized plasma

KW - Numerical stability

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3-D discrete dispersion relation, numerical stability, and accuracy of the hybrid FDTD model for cold magnetized toroidal plasma

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