Bridging High-Density, Electron Beam Coronal Transport and Deep Chromospheric Heating in Stellar Flares

TL;DR

This paper links high-energy electron beam transport with deep chromospheric heating in stellar flares, explaining optical and NUV emissions through advanced modeling of electron energy redistribution and heating.

Contribution

It introduces a semi-empirical model that accounts for enhanced chromospheric heating and optical emissions by incorporating recent numerical solutions of electron-plasma wave interactions.

Findings

Models produce optical and NUV continua with T > 12,000 K.

Explains observed color temperatures and Balmer jump in M dwarf flares.

Highlights the importance of high-energy electron redistribution in flare heating.

Abstract

The optical and near-ultraviolet (NUV) continuum radiation in M dwarf flares is thought to be the impulsive response of the lower stellar atmosphere to magnetic energy release and electron acceleration at coronal altitudes. This radiation is sometimes interpreted as evidence of a thermal photospheric spectrum with $T \approx 10^4$ K. However, calculations show that standard solar flare coronal electron beams lose their energy in a thick target of gas in the upper and middle chromosphere (log$_{10}$ column mass /[g cm$^{-2}$] $\lesssim -3$). At larger beam injection fluxes, electric fields and instabilities are expected to further inhibit propagation to low altitudes. We show that recent numerical solutions of the time-dependent equations governing the power-law electrons and background coronal plasma (Langmuir and ion-acoustic) waves from Kontar et al. produce order-of-magnitude larger heating rates than occur in the deep chromosphere through standard solar flare electron beam power-law distributions. We demonstrate that the redistribution of beam energy above $E \gtrsim 100$ keV in this theory results in a local heating maximum that is similar to a radiative-hydrodynamic model with a large, low-energy cutoff and a hard power-law index. We use this semi-empirical forward modeling approach to produce opaque NUV and optical continua at gas temperatures $T \gtrsim 12,000$ K over the deep chromosphere with log$_{10}$ column mass /[g cm$^{-2}$] of $-1.2$ to $-2.3$. These models explain the color temperatures and Balmer jump strengths in high-cadence M dwarf flare observations, and they clarify the relation among atmospheric, radiation, and optical color temperatures in stellar flares.