Perpendicular Ion Heating by Reduced Magnetohydrodynamic Turbulence

Abstract

Recent theoretical studies argue that the rate of stochastic ion heating in low-frequency Alfv\'en-wave turbulence is given by Q = c1 [(δ u)3 /] (-c2/ε), where δ u is the rms turbulent velocity at the scale of the ion gyroradius , ε = δ u/v i, v i is the perpendicular ion thermal speed, and c1 and c2 are dimensionless constants. We test this theoretical result by numerically simulating test particles interacting with strong reduced magnetohydrodynamic (RMHD) turbulence. The heating rates in our simulations are well fit by this formula. The best-fit values of c1 are 1. The best-fit values of c2 decrease (i.e., stochastic heating becomes more effective) as the grid size and Reynolds number of the RMHD simulations increase. As an example, in a 10242 × 256 RMHD simulation with a dissipation wavenumber of order the inverse ion gyroradius, we find c2 = 0.21. We show that stochastic heating is significantly stronger in strong RMHD turbulence than in a field of randomly phased Alfv\'en waves with the same power spectrum, because coherent structures in strong RMHD turbulence increase orbit stochasticity in the regions where ions are heated most strongly. We find that c1 increases by a factor of 3 while c2 changes very little as the ion thermal speed increases from values v A to values v A, where v A is the Alfv\'en speed. We discuss the importance of these results for perpendicular ion heating in the solar wind.