Observational Test of Stochastic Heating in Low-$\beta$ Fast Solar Wind Streams

TL;DR

This study uses Helios 2 spacecraft data to evaluate whether stochastic heating by turbulence can explain the observed perpendicular proton heating in low-beta fast solar wind streams, finding supporting evidence for this mechanism.

Contribution

It provides empirical validation that stochastic heating can account for proton perpendicular heating in low-beta solar wind streams, using in-situ measurements and analytical modeling.

Findings

Stochastic heating rate matches empirical heating rate under certain conditions.

Results are consistent with numerical simulations of turbulence-driven heating.

Supports stochastic heating as a key process in solar wind proton heating.

Abstract

Spacecraft measurements show that protons undergo substantial perpendicular heating during their transit from the Sun to the outer heliosphere. In this paper, we use {\em Helios~2} measurements to investigate whether stochastic heating by low-frequency turbulence is capable of explaining this perpendicular heating. We analyze {\em Helios~2} magnetic-field measurements in low-$\beta$ fast-solar-wind streams between heliocentric distances $r=0.29$ AU and $r=0.64$ AU to determine the rms amplitude of the fluctuating magnetic field, $\delta B_{\rm p}$, near the proton gyroradius scale $\rho_{\rm p}$. We then evaluate the stochastic heating rate $Q_{\perp \rm stoch}$ using the measured value of $\delta B_{\rm p}$ and a previously published analytical formula for $Q_{\perp \rm stoch}$. Using {\em Helios} measurements we estimate the `empirical' perpendicular heating rate $Q_{\perp \rm emp} = (k_{\rm B}/m_{\rm p}) B V (d/dr) (T_{\perp \rm p}/B)$ that is needed to explain the $T_{\perp \rm p}$ profile. We find that $Q_{\perp \rm stoch} \sim Q_{\perp \rm emp}$, but only if a key dimensionless constant appearing in the formula for $Q_{\perp \rm stoch}$ lies within a certain range of values. This range is approximately the same throughout the radial interval that we analyze and is consistent with the results of numerical simulations of the stochastic heating of test particles in reduced magnetohydrodynamic turbulence. These results support the hypothesis that stochastic heating accounts for much of the perpendicular proton heating occurring in low-$\beta$ fast-wind streams.