Computational modeling of fully ionized magnetized plasmas using the fluid approximation

D. D. Schnack; D. C. Barnes; D. P. Brennan; C. C. Hegna; E. Held; C. C. Kim; S. E. Kruger; A. Y. Pankin; C. R. Sovinec

doi:10.1063/1.2183738

Computational modeling of fully ionized magnetized plasmas using the fluid approximation

D. D. Schnack, D. C. Barnes, D. P. Brennan, C. C. Hegna, E. Held, C. C. Kim, S. E. Kruger, A. Y. Pankin, C. R. Sovinec

Research output: Contribution to journal › Article › peer-review

58 Scopus citations

Abstract

Strongly magnetized plasmas are rich in spatial and temporal scales, making a computational approach useful for studying these systems. The most accurate model of a magnetized plasma is based on a kinetic equation that describes the evolution of the distribution function for each species in six-dimensional phase space. High dimensionality renders this approach impractical for computations for long time scales. Fluid models are an approximation to the kinetic model. The reduced dimensionality allows a wider range of spatial andor temporal scales to be explored. Computational modeling requires understanding the ordering and closure approximations, the fundamental waves supported by the equations, and the numerical properties of the discretization scheme. Several ordering and closure schemes are reviewed and discussed, as are their normal modes, and algorithms that can be applied to obtain a numerical solution.

Original language	English (US)
Article number	058103
Journal	Physics of Plasmas
Volume	13
Issue number	5
DOIs	https://doi.org/10.1063/1.2183738
State	Published - May 2006
Externally published	Yes

All Science Journal Classification (ASJC) codes

Condensed Matter Physics

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10.1063/1.2183738

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title = "Computational modeling of fully ionized magnetized plasmas using the fluid approximation",

abstract = "Strongly magnetized plasmas are rich in spatial and temporal scales, making a computational approach useful for studying these systems. The most accurate model of a magnetized plasma is based on a kinetic equation that describes the evolution of the distribution function for each species in six-dimensional phase space. High dimensionality renders this approach impractical for computations for long time scales. Fluid models are an approximation to the kinetic model. The reduced dimensionality allows a wider range of spatial andor temporal scales to be explored. Computational modeling requires understanding the ordering and closure approximations, the fundamental waves supported by the equations, and the numerical properties of the discretization scheme. Several ordering and closure schemes are reviewed and discussed, as are their normal modes, and algorithms that can be applied to obtain a numerical solution.",

author = "Schnack, \{D. D.\} and Barnes, \{D. C.\} and Brennan, \{D. P.\} and Hegna, \{C. C.\} and E. Held and Kim, \{C. C.\} and Kruger, \{S. E.\} and Pankin, \{A. Y.\} and Sovinec, \{C. R.\}",

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AU - Schnack, D. D.

AU - Barnes, D. C.

AU - Brennan, D. P.

AU - Hegna, C. C.

AU - Held, E.

AU - Kim, C. C.

AU - Kruger, S. E.

AU - Pankin, A. Y.

AU - Sovinec, C. R.

PY - 2006/5

Y1 - 2006/5

N2 - Strongly magnetized plasmas are rich in spatial and temporal scales, making a computational approach useful for studying these systems. The most accurate model of a magnetized plasma is based on a kinetic equation that describes the evolution of the distribution function for each species in six-dimensional phase space. High dimensionality renders this approach impractical for computations for long time scales. Fluid models are an approximation to the kinetic model. The reduced dimensionality allows a wider range of spatial andor temporal scales to be explored. Computational modeling requires understanding the ordering and closure approximations, the fundamental waves supported by the equations, and the numerical properties of the discretization scheme. Several ordering and closure schemes are reviewed and discussed, as are their normal modes, and algorithms that can be applied to obtain a numerical solution.

AB - Strongly magnetized plasmas are rich in spatial and temporal scales, making a computational approach useful for studying these systems. The most accurate model of a magnetized plasma is based on a kinetic equation that describes the evolution of the distribution function for each species in six-dimensional phase space. High dimensionality renders this approach impractical for computations for long time scales. Fluid models are an approximation to the kinetic model. The reduced dimensionality allows a wider range of spatial andor temporal scales to be explored. Computational modeling requires understanding the ordering and closure approximations, the fundamental waves supported by the equations, and the numerical properties of the discretization scheme. Several ordering and closure schemes are reviewed and discussed, as are their normal modes, and algorithms that can be applied to obtain a numerical solution.

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Computational modeling of fully ionized magnetized plasmas using the fluid approximation

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