Hard X-rays from the deep solar atmosphere. An unusual UV burst with flare properties

TL;DR

This study reports a unique solar event exhibiting both UV burst and hard X-ray flare characteristics in the lower atmosphere, revealing high-temperature plasma and particle acceleration with limited UV spectral signatures.

Contribution

It presents the first detailed analysis of a hybrid UV burst and hard X-ray flare event occurring in the low solar atmosphere, combining multi-wavelength observations and spectral modeling.

Findings

Plasma temperatures exceeded 15 MK during the event.

Nonthermal energy output was approximately 3×10^{27} erg/s.

The event was confined mainly to the chromosphere with limited UV signatures.

Abstract

Explosive transient events occur throughout the solar atmosphere. The differing manifestations range from coronal mass ejections to Ellerman bombs. The former may have negligible signatures in the lower atmosphere, and the latter may have negligible nonthermal emissions such as hard X-radiation. A solar flare generally involves a broad range of emission signatures. Using a suite of four space-borne telescopes, we report a solar event that combines aspects of simple UV bursts and hard X-ray emitting flares at the same time. The event is a compact C-class flare in active region AR11861, SOL2013-10-12T00:30. By fitting a combined isothermal and nonthermal model to the hard X-ray spectrum, we inferred plasma temperatures in excess of 15\,MK and a nonthermal power of about $3\times10^{27}$\,erg\,s$^{-1}$ in this event. Despite these high temperatures and evidence for nonthermal particles, the flare was mostly confined to the chromosphere. However, the event lacked clear signatures of UV spectral lines, such as the Fe\,{\sc xii} 1349\,\AA\ and Fe\,{\sc xxi} 1354\,\AA\ emission lines, which are characteristic of emission from hotter plasma with a temperature over 1\,MK. Moreover, the event exhibited very limited signatures in the extreme-UV wavelengths. Our study indicates that a UV burst -- hard X-ray flare hybrid phenomenon exists in the low solar atmosphere. Plasma that heats to high temperatures coupled with particle acceleration by magnetic energy that is released directly in the lower atmosphere sheds light on the nature of active region core heating and on inferences of flare signatures.