# Self-induced Scattering of Strahl Electrons in the Solar Wind

**Authors:** Daniel Verscharen (UCL, UNH), Benjamin D. G. Chandran (UNH) and, Seong-Yeop Jeong (UCL), Chadi S. Salem (UCB), Marc P. Pulupa (UCB) and, Stuart D. Bale (UCB, Imperial College)

arXiv: 1906.02832 · 2019-12-04

## TL;DR

This paper develops a theoretical framework to identify the oblique FM/W microinstability as the primary mechanism scattering strahl electrons into the halo in the solar wind, supported by data comparisons and predictions for upcoming spacecraft measurements.

## Contribution

It introduces a new analytical model for the oblique FM/W instability threshold and confirms its relevance for solar wind electron scattering through data comparison.

## Key findings

- Oblique FM/W instability effectively scatters strahl electrons into the halo.
- Analytic thresholds for the instability are derived for different plasma beta regimes.
- Comparison with Wind data supports the instability's role in solar wind electron dynamics.

## Abstract

We investigate the scattering of strahl electrons by microinstabilities as a mechanism for creating the electron halo in the solar wind. We develop a mathematical framework for the description of electron-driven microinstabilities and discuss the associated physical mechanisms. We find that an instability of the oblique fast-magnetosonic/whistler (FM/W) mode is the best candidate for a microinstability that scatters strahl electrons into the halo. We derive approximate analytic expressions for the FM/W instability threshold in two different $\beta_{\mathrm c}$ regimes, where $\beta_{\mathrm c}$ is the ratio of the core electrons' thermal pressure to the magnetic pressure, and confirm the accuracy of these thresholds through comparison with numerical solutions to the hot-plasma dispersion relation. We find that the strahl-driven oblique FM/W instability creates copious FM/W waves under low-$\beta_{\mathrm c}$ conditions when $U_{0\mathrm s}\gtrsim 3w_{\mathrm c}$, where $U_{0\mathrm s}$ is the strahl speed and $w_{\mathrm c}$ is the thermal speed of the core electrons. These waves have a frequency of about half the local electron gyrofrequency. We also derive an analytic expression for the oblique FM/W instability for $\beta_{\mathrm c}\sim 1$. The comparison of our theoretical results with data from the \emph{Wind} spacecraft confirms the relevance of the oblique FM/W instability for the solar wind. The whistler heat-flux, ion-acoustic heat-flux, kinetic-Alfv\'en-wave heat-flux, and electrostatic electron-beam instabilities cannot fulfill the requirements for self-induced scattering of strahl electrons into the halo. We make predictions for the electron strahl close to the Sun, which will be tested by measurements from \emph{Parker Solar Probe} and \emph{Solar Orbiter}.

## Full text

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## Figures

11 figures with captions in the complete paper: https://tomesphere.com/paper/1906.02832/full.md

## References

85 references — full list in the complete paper: https://tomesphere.com/paper/1906.02832/full.md

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Source: https://tomesphere.com/paper/1906.02832