English

Parallel diffusion operator for magnetized plasmas with improved spectral fidelity

Plasma Physics 2024-12-04 v1

Abstract

Diffusive transport processes in magnetized plasmas are highly anisotropic, with fast parallel transport along the magnetic field lines sometimes faster than perpendicular transport by orders of magnitude. This constitutes a major challenge for describing non-grid-aligned magnetic structures in Eulerian (grid-based) simulations. The present paper describes and validates a new method for parallel diffusion in magnetized plasmas based on the anti-symmetry representation [Halpern and Waltz, Phys. Plasmas 25, 060703 (2018)]. In the anti-symmetry formalism, diffusion manifests as a flow operator involving the logarithmic derivative of the transported quantity. Qualitative plane wave analysis shows that the new operator naturally yields better discrete spectral resolution compared to its conventional counterpart. Numerical simulations comparing the new method against existing finite difference methods are carried out, showing significant improvement. In particular, we find that combining anti-symmetry with finite differences in diagonally staggered grids essentially eliminates the so-called "artificial numerical diffusion" that affects conventional finite difference and finite volume methods.

Keywords

Cite

@article{arxiv.2412.01927,
  title  = {Parallel diffusion operator for magnetized plasmas with improved spectral fidelity},
  author = {Federico D. Halpern and Min-Gu Yoo and Brendan Lyons and Juan Diego Colmenares},
  journal= {arXiv preprint arXiv:2412.01927},
  year   = {2024}
}

Comments

Submitted to Computer Physics Communication

R2 v1 2026-06-28T20:20:26.192Z