Nature of stochastic ion heating in the solar wind: testing the dependence on plasma beta and turbulence amplitude

Abstract

The solar wind undergoes significant heating as it propagates away from the Sun; the exact mechanisms responsible for this heating are not yet fully understood. We present for the first time a statistical test for one of the proposed mechanisms, stochastic ion heating. We use the amplitude of magnetic field fluctuations near the proton gyroscale as a proxy for the ratio of gyroscale velocity fluctuations to perpendicular (with respect to the magnetic field) proton thermal speed, defined as εp. Enhanced proton temperatures are observed when εp is larger than a critical value ( 0.019 - 0.025). This enhancement strongly depends on the proton plasma beta (β||p); when β||p 1 only the perpendicular proton temperature T increases, while for β||p 1 increased parallel and perpendicular proton temperatures are both observed. For εp smaller than the critical value and β||p 1 no enhancement of Tp is observed while for β||p 1 minor increases in T are measured. The observed change of proton temperatures across a critical threshold for velocity fluctuations is in agreement with the stochastic ion heating model of Chandran et al. (2010). We find that εp > ε crit in 76\% of the studied periods implying that stochastic heating may operate most of the time in the solar wind at 1 AU.