# Electron energy partition across interplanetary shocks: I. Methodology   and Data Product

**Authors:** Lynn B. Wilson III, Li-Jen Chen, Shan Wang, Steven J. Schwartz, Drew, L. Turner, Michael L. Stevens, Justin C. Kasper, Adnane Osmane, Damiano, Caprioli, Stuart D. Bale, Marc P. Pulupa, Chadi S. Salem, Katherine A., Goodrich

arXiv: 1902.01476 · 2019-07-10

## TL;DR

This study analyzes electron velocity distribution functions near interplanetary shocks, demonstrating that a self-similar distribution better fits core electrons than a Maxwellian, revealing insights into particle scattering processes.

## Contribution

It introduces a novel statistical methodology for fitting electron VDFs with self-similar functions, showing their superiority over Maxwellians in modeling core electrons.

## Key findings

- Core electron distributions are better fit by self-similar functions than Maxwellians.
- Kappa exponents range: 5.40–10.2 for core, 3.58–5.34 for halo, 3.40–5.16 for beam/strahl.
- Detailed fit procedures and data products are described.

## Abstract

Analysis of 15314 electron velocity distribution functions (VDFs) within $\pm$2 hours of 52 interplanetary (IP) shocks observed by the \emph{Wind} spacecraft near 1 AU are introduced. The electron VDFs are fit to the sum of three model functions for the cold dense core, hot tenuous halo, and field-aligned beam/strahl component. The best results were found by modeling the core as either a bi-kappa or a symmetric (or asymmetric) bi-self-similar velocity distribution function, while both the halo and beam/strahl components were best fit to bi-kappa velocity distribution function. This is the first statistical study to show that the core electron distribution is better fit to a self-similar velocity distribution function than a bi-Maxwellian under all conditions. The self-similar distribution deviation from a Maxwellian is a measure of inelasticity in particle scattering from waves and/or turbulence. The range of values defined by the lower and upper quartiles for the kappa exponents are $\kappa{\scriptstyle_{ec}}$ $\sim$ 5.40--10.2 for the core, $\kappa{\scriptstyle_{eh}}$ $\sim$ 3.58--5.34 for the halo, and $\kappa{\scriptstyle_{eb}}$ $\sim$ 3.40--5.16 for the beam/strahl. The lower-to-upper quartile range of symmetric bi-self-similar core exponents are $s{\scriptstyle_{ec}}$ $\sim$ 2.00--2.04, and asymmetric bi-self-similar core exponents are $p{\scriptstyle_{ec}}$ $\sim$ 2.20--4.00 for the parallel exponent, and $q{\scriptstyle_{ec}}$ $\sim$ 2.00--2.46 for the perpendicular exponent. The nuanced details of the fit procedure and description of resulting data product are also presented. The statistics and detailed analysis of the results are presented in Paper II and Paper III of this three-part study.

## Full text

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## Figures

16 figures with captions in the complete paper: https://tomesphere.com/paper/1902.01476/full.md

## References

157 references — full list in the complete paper: https://tomesphere.com/paper/1902.01476/full.md

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Source: https://tomesphere.com/paper/1902.01476