Time Integrator Agnostic Charge Conserving Finite Element PIC

Developing particle-in-cell (PIC) methods using finite element basis sets, and without auxiliary divergence cleaning methods, was a long standing problem until recently. It was shown that if consistent spatial basis functions are used, one can indeed create a methodology that was charge conserving,...

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Bibliographic Details
Published in:arXiv.org 2021-02
Main Authors: O'Connor, Scott, Crawford, Zane D, Ramachandran, O H, Luginsland, John, Shanker, B
Format: Article
Language:English
Subjects:
Basis functions
Debye length
Divergence
Finite element method
Mass ratios
Methodology
Neutral beams
Particle beams
Particle in cell technique
Wave equations
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Summary:Developing particle-in-cell (PIC) methods using finite element basis sets, and without auxiliary divergence cleaning methods, was a long standing problem until recently. It was shown that if consistent spatial basis functions are used, one can indeed create a methodology that was charge conserving, albeit using a leap-frog time stepping method. While this is a significant advance, leap frog schemes are only conditionally stable and time step sizes are closely tied to the underlying mesh. Ideally, to take full advantage of advances in finite element methods (FEMs), one needs a charge conserving PIC methodology that is agnostic to the time stepping method. This is the principal contribution of this paper. In what follows, we shall develop this methodology, prove that both charge and Gauss' laws are discretely satisfied at every time step, provide the necessary details to implement this methodology for both the wave equation FEM and Maxwell Solver FEM, and finally demonstrate its efficacy on a suite of test problems. The method will be demonstrated by single particle evolution, non-neutral beams with space-charge, and adiabatic expansion of a neutral plasma, where the debye length has been resolved, and real mass ratios are used.
ISSN:2331-8422
DOI:10.48550/arxiv.2102.06248