Stochastic Ion Acceleration by the Ion-cyclotron Instability in a Growing Magnetic Field

Abstract

Using 1D and 2D particle-in-cell (PIC) simulations of a plasma with a growing magnetic field B, we show that ions can be stochastically accelerated by the ion-cyclotron (IC) instability. As B grows, an ion pressure anisotropy p,i > p||,i arises, due to the adiabatic invariance of the ion magnetic moment (p||,i and p,i are the ion pressures parallel and perpendicular to B). When initially βi = 0.5 (βi 8π pi/|B|2, where pi is the ion isotropic pressure), the pressure anisotropy is limited mainly by inelastic pitch-angle scattering provided by the IC instability, which in turn produces a non-thermal tail in the ion energy spectrum. After B is amplified by a factor 2.7, this tail can be approximated as a power-law of index 3.4 plus two non-thermal bumps, and accounts for 2-3\% of the ions and 18\% of their kinetic energy. On the contrary, when initially βi =2, the ion scattering is dominated by the mirror instability and the acceleration is suppressed. This implies that efficient ion acceleration requires that initially βi 1. Although we focus on cases where B is amplified by plasma shear, we check that the acceleration occurs similarly if B grows due to plasma compression. Our results are valid in a sub-relativistic regime where the ion thermal energy is 10\% of the ion rest mass energy. This acceleration process can thus be relevant in the inner region of low-luminosity accretion flows around black holes.