# The Role of Energy Diffusion in the Deposition of Energetic Electron   Energy in Solar and Stellar Flares

**Authors:** Natasha L. S. Jeffrey, Eduard P. Kontar, Lyndsay Fletcher

arXiv: 1906.01887 · 2019-08-09

## TL;DR

This study uses kinetic modeling to show how energy diffusion and thermalization of electrons in the solar corona influence energy deposition in solar flares, revealing delayed heating effects that can diagnose flare properties.

## Contribution

It introduces a full collisional warm-target model (WTM) for electron transport, improving upon the cold thick-target model by including thermalization and plasma properties.

## Key findings

- Energy deposition depends on coronal plasma properties.
- Thermalization increases non-thermal energy transfer to the chromosphere.
- Delayed heating occurs over seconds, affecting flare diagnostics.

## Abstract

During solar flares, a large fraction of the released magnetic energy is carried by energetic electrons that transfer and deposit energy in the Sun's atmosphere. Electron transport is often approximated by a cold thick-target model (CTTM), assuming that electron energy is much larger than the temperature of the ambient plasma, and electron energy evolution is modeled as a systematic loss. Using kinetic modeling of electrons, we re-evaluate the transport and deposition of flare energy. Using a full collisional warm-target model (WTM), we account for electron thermalization and for the properties of the ambient coronal plasma such as its number density, temperature and spatial extent. We show that the deposition of non-thermal electron energy in the lower atmosphere is highly dependent on the properties of the flaring coronal plasma. In general, thermalization and a reduced WTM energy loss rate leads to an increase of non-thermal energy transferred to the chromosphere, and the deposition of non-thermal energy at greater depths. The simulations show that energy is deposited in the lower atmosphere initially by high energy non-thermal electrons, and later by lower energy non-thermal electrons that partially or fully thermalize in the corona, over timescales of seconds, unaccounted for in previous studies. This delayed heating may act as a diagnostic of both the injected non-thermal electron distribution and the coronal plasma, vital for constraining flare energetics.

## Full text

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## Figures

22 figures with captions in the complete paper: https://tomesphere.com/paper/1906.01887/full.md

## References

75 references — full list in the complete paper: https://tomesphere.com/paper/1906.01887/full.md

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Source: https://tomesphere.com/paper/1906.01887