An Asymptotic Preserving Maxwell Solver Resulting in the Darwin Limit of Electrodynamics

An Asymptotic Preserving Maxwell Solver Resulting in the Darwin Limit of Electrodynamics

In plasma simulations, where the speed of light divided by a characteristic length is at a much higher frequency than other relevant parameters in the underlying system, such as the plasma frequency, implicit methods begin to play an important role in generating efficient solutions in these multi-sc...

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Veröffentlicht in:Journal of scientific computing 2017-06, Vol.71 (3), p.959-993
Hauptverfasser: Cheng, Yingda, Christlieb, Andrew J., Guo, Wei, Ong, Benjamin
Format: Artikel
Sprache:eng
Schlagworte:
Algorithms
Asymptotic methods
Asymptotic properties
Boundary conditions
Computational Mathematics and Numerical Analysis
Electric fields
Electrodynamics
Implicit methods
Magnetic fields
Mathematical and Computational Engineering
Mathematical and Computational Physics
Mathematics
Mathematics and Statistics
Maxwell's equations
Method of lines
Methods
Partial differential equations
Plasma
Plasma frequencies
Simulation
Theoretical
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Zusammenfassung:In plasma simulations, where the speed of light divided by a characteristic length is at a much higher frequency than other relevant parameters in the underlying system, such as the plasma frequency, implicit methods begin to play an important role in generating efficient solutions in these multi-scale problems. Under conditions of scale separation, one can rescale Maxwell’s equations in such a way as to give a magneto static limit known as the Darwin approximation of electromagnetics. In this work, we present a new approach to solve Maxwell’s equations based on a Method of Lines Transpose ( MOL T ) formulation, combined with a fast summation method with computational complexity O ( N log N ) , where N is the number of grid points (particles). Under appropriate scaling, we show that the proposed schemes result in asymptotic preserving methods that can recover the Darwin limit of electrodynamics.
ISSN:0885-7474
1573-7691
DOI:10.1007/s10915-016-0328-0