Alpha-Proton Differential Flow of A Coronal Mass Ejection at 15 Solar Radii

Abstract

Alpha-proton differential flow (Vα p) of coronal mass ejections (CMEs) and solar wind from the Sun to 1 au and beyond could influence the instantaneous correspondence of absolute abundances of alpha particles (He2+/H+) between solar corona and interplanetary space as the abundance of a coronal source can vary with time. Previous studies based on Ulysses and Helios showed that Vα p is negligible within CMEs from 5 to 0.3 au, similar to slow solar wind (< 400 km s-1). However, recent new observations using Parker Solar Probe (PSP) revealed that the Vα p of slow wind increases to 60 km s-1 inside 0.1 au. It is significant to answer whether the Vα p of CMEs exhibits the similar behavior near the Sun. In this Letter, we report the Vα p of a CME measured by PSP at 15 R for the first time, which demonstrates that the Vα p of CMEs is obvious and complex inside 0.1 au while keeps lower than the local Alfv\'en speed. A very interesting point is that the same one CME duration can be divided into A and B intervals clearly with Coulomb number below and beyond 0.5, respectively. The means of Vα p and alpha-to-proton temperature ratios of interval A (B) is 96.52 (21.96) km s-1 and 7.65 (2.23), respectively. This directly illustrates that Coulomb collisions play an important role in reducing the non-equilibrium features of CMEs. Our study indicates that the absolute elemental abundances of CMEs also might vary during their propagation.