Electron heat conduction in the solar wind: transition from Spitzer-H\"arm to the collisionless limit

Abstract

We use a statistically significant set of measurements to show that the field-aligned electron heat flux q in the solar wind at 1 AU is consistent with the Spitzer-H\"arm collisional heat flux qsh for temperature gradient scales larger than a few mean free paths LT 3.5 ~λfp. This represents about 65% of the measured data and corresponds primarily to high β, weakly collisional plasma ('slow solar wind'). In the more collisionless regime λfp/LT 0.28, the electron heat flux is limited to q/q0 0.3, independent of mean free path, where q0 is the 'free-streaming' value; the measured q does not achieve the full q0. This constraint q/q0 0.3 might be attributed to wave-particle interactions, an interplanetary electric potential, or inherent flux limitation. We also show a βe dependence to these results that is consistent with a local radial electron temperature profile Te r-α that is a function of the thermal electron beta α = α(βe) and that the β dependence of the collisionless regulation constraint is not obviously consistent with a whistler heat flux instability. We discuss the results in a broader astrophysical context.