Reinterpreting the sunward electron deficit: Implications for solar wind acceleration and core population formation

TL;DR

This study reinterprets sunward electron cutoff energies by considering magnetic traps, revealing that the Sun's electrostatic potential plays a more significant role in solar wind acceleration and electron population formation than previously thought.

Contribution

It introduces a new framework accounting for magnetic traps that explains electron cutoff energies and their relation to the Sun's electrostatic potential.

Findings

Electron cutoff energy reflects local trap potential, not total Sun potential.

Moving magnetic traps influence electron energy loss and escape.

The Sun's electrostatic potential significantly impacts solar wind acceleration.

Abstract

This paper re-evaluates the relationship between the observed sunward electron cutoff energy and the depth of the Sun's global electrostatic potential. It investigates whether taking into account the effects of local traps formed by magnetic fluctuations provides an alternative explanation for the observed electron deficit. The fluctuations of the highly variable interplanetary magnetic field form a series of shallow magnetic mirror traps that move at approximately the speed of the solar wind. The study investigates the dynamics of electrons as they move outward against an attractive solar electrostatic potential and interact with these traps. By following the motion of the electrons using first-principles calculations, we assess the effect of the traps on the velocity distribution of the particles. Electrons that escape the local trap continue to lose energy as they move outward until they are eventually captured by subsequent traps, preventing them from returning to the observer as sunward-moving particles. We derive a mathematical expression for the cutoff velocity, defined as the limit beyond which particles can no longer overtake the outer endpoint of a local trap. It turns out that the observed cutoff energy characterizes only the local potential drop within a trap, rather than the total depth of the Sun's potential well. The true potential well can be significantly deeper, scaled by the ratio of the radial distance from the Sun to the trap size. Furthermore, electrons captured by these moving traps contribute to the formation of the solar wind core population. The Sun's electrostatic potential is a more significant factor in solar wind acceleration than previously interpreted from cutoff data. The interaction between electrostatic deceleration and moving magnetic traps provides a new framework for understanding the origin and behavior of the solar wind core electrons.