Energetic Particle Diffusion In Critically Balanced Turbulence
Abstract
Observations and modelling suggest that the fluctuations in magnetised plasmas exhibit scale-dependent anisotropy, with more energy in the fluctuations perpendicular to the mean magnetic field than in the parallel fluctuations and the anisotropy increasing at smaller scales. The scale-dependence of the anisotropy has not been studied in full-orbit simulations of particle transport in turbulent plasmas so far. In this paper, we construct a model of critically balanced turbulence, as suggested by \cite{GoSr1995}, and calculate energetic particle spatial diffusion coefficients using full-orbit simulations. The model uses an enveloped turbulence approach, where each 2-dimensional wave mode with wavenumber is packed into envelopes of length following the critical balance condition, , with the wave mode parameters changing between envelopes. Using full-orbit particle simulations, we find that both the parallel and perpendicular diffusion coefficients increase by a factor 2, compared to previous models with scale-independent anisotropy.
Cite
@article{arxiv.1304.5399,
title = {Energetic Particle Diffusion In Critically Balanced Turbulence},
author = {T. Laitinen and S. Dalla and J. Kelly and M. Marsh},
journal= {arXiv preprint arXiv:1304.5399},
year = {2013}
}