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 (δ B/B ≈ 1) 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 <( r)2> inside the stochastic Fermi accelerator is superdiffusive, <( r)2> tar, with ar 1.2-1.6, for the high energy electrons with kinetic energy (W) larger than 1 MeV, and it is normal (ar=1) for the heated low energy (W< 10 keV) 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 (λsc). The smaller λsc is, the faster the electrons and ions escape from the acceleration volume. (3) The mean displacement in energy < W> taW is strongly enhanced inside the acceleration volume (aW=1.5- 2.5) for the high energy particles compared to the thermal low energy particles (aW=0.4), i.e.\ high energy particles undergo an enhanced systematic gain in energy.(4) The mean-square displacement in energy <W2> is superdiffusive for the high energy particles and normal for the low energy, heated particles.