Superdiffusive Stochastic Fermi Acceleration in Space and Energy
Abstract
We analyze the transport properties of charged particles (ions and electrons) interacting with randomly formed magnetic scatterers (e.g.\ large scale local ``magnetic fluctuations'' or ``coherent magnetic irregularities'' usually present in strongly turbulent plasmas), using the energization processes proposed initially by Fermi in 1949. The scatterers are formed by large scale local fluctuations () and are randomly distributed inside the unstable magnetic topology. We construct a 3D grid on which a small fraction of randomly chosen grid points are acting as scatterers. In particular, we study how a large number of test particles are accelerated and transported inside a collection of scatterers in a finite volume. Our main results are: (1) The spatial mean-square displacement inside the stochastic Fermi accelerator is superdiffusive, with , for the high energy electrons with kinetic energy larger than , and it is normal () for the heated low energy electrons. (2) The transport properties of the high energy particles are closely related with the mean-free path that the particles travel in-between the scatterers (). The smaller is, the faster the electrons and ions escape from the acceleration volume. (3) The mean displacement in energy is strongly enhanced inside the acceleration volume for the high energy particles compared to the thermal low energy particles (), i.e.\ high energy particles undergo an enhanced systematic gain in energy.(4) The mean-square displacement in energy is superdiffusive for the high energy particles and normal for the low energy, heated particles.
Cite
@article{arxiv.1911.07973,
title = {Superdiffusive Stochastic Fermi Acceleration in Space and Energy},
author = {Nikos Sioulas and Heinz Isliker and Loukas Vlahos and Argyris Koumtzis and Theophilos Pisokas},
journal= {arXiv preprint arXiv:1911.07973},
year = {2020}
}
Comments
11 pages, 8 figures, accepted for publication in MNRAS