The Atmospheric Response to High Nonthermal Electron Beam Fluxes in Solar Flares I: Modeling the Brightest NUV Footpoints in the X1 Solar Flare of 2014 March 29

TL;DR

This study models the atmospheric response to intense nonthermal electron beams in a solar flare, successfully reproducing observed ultraviolet continuum brightness and emission line asymmetries using radiative-hydrodynamic simulations.

Contribution

It introduces a detailed radiative-hydrodynamic model that explains the UV emission and line asymmetries in a major solar flare based on high flux electron beam interactions.

Findings

NUV continuum emission is consistent with hydrogen recombination radiation.

A dense chromospheric condensation explains the observed emission brightness.

The model reproduces asymmetric Fe II line profiles during the impulsive phase.

Abstract

The 2014 March 29 X1 solar flare (SOL20140329T17:48) produced bright continuum emission in the far- and near-ultraviolet (NUV) and highly asymmetric chromospheric emission lines, providing long-sought constraints on the heating mechanisms of the lower atmosphere in solar flares. We analyze the continuum and emission line data from the Interface Region Imaging Spectrograph (IRIS) of the brightest flaring magnetic footpoints in this flare. We compare the NUV spectra of the brightest pixels to new radiative-hydrodynamic predictions calculated with the RADYN code using constraints on a nonthermal electron beam inferred from the collisional thick-target modeling of hard X-ray data from RHESSI. We show that the atmospheric response to a high beam flux density satisfactorily achieves the observed continuum brightness in the NUV. The NUV continuum emission in this flare is consistent with hydrogen (Balmer) recombination radiation that originates from low optical depth in a dense chromospheric condensation and from the stationary beam-heated layers just below the condensation. A model producing two flaring regions (a condensation and stationary layers) in the lower atmosphere is also consistent with the asymmetric Fe II chromospheric emission line profiles observed in the impulsive phase.