Time-splitting methods for the cold-plasma model using Finite Element Exterior Calculus
Abstract
In this work we propose a high-order structure-preserving discretization of the cold plasma model which describes the propagation of electromagnetic waves in magnetized plasmas. By utilizing B-Splines Finite Elements Exterior Calculus, we derive a space discretization that preserves the underlying Hamiltonian structure of the model, and we study two stable time-splitting geometrical integrators. We approximate an incoming wave boundary condition in such a way that the resulting schemes are compatible with a time-harmonic / transient decomposition of the solution, which allows us to establish their long-time stability. This approach readily applies to curvilinear and complex domains. We perform a numerical study of these schemes which compares their cost and accuracy against a standard Crank-Nicolson time integrator, and we run realistic simulations where the long-term behaviour is assessed using frequency-domain solutions. Our solvers are implemented in the Python library Psydac which makes them memory-efficient, parallel and essentially three-dimensional.
Cite
@article{arxiv.2501.16991,
title = {Time-splitting methods for the cold-plasma model using Finite Element Exterior Calculus},
author = {Elena Moral Sánchez and Martin Campos Pinto and Yaman Güçlü and Omar Maj},
journal= {arXiv preprint arXiv:2501.16991},
year = {2025}
}
Comments
32 pages, 18 figures