Radio and X-ray Observations of Short-lived Episodes of Electron Acceleration in a Solar Microflare

TL;DR

This study uses multi-wavelength observations to analyze multiple, short-lived electron acceleration episodes during a solar microflare, revealing distinct electron populations in different magnetic loops.

Contribution

It provides detailed analysis of multiple acceleration episodes in a microflare using combined radio, X-ray, and EUV data, highlighting differences in electron populations.

Findings

Multiple acceleration episodes observed during the microflare.

Radio and X-ray sources originate from separate electron populations.

Derived magnetic field and electron parameters vary between episodes.

Abstract

Solar flares are sudden energy release events in the solar corona, resulting from magnetic reconnection, that accelerates particles and heats the ambient plasma. During a flare, there are often multiple, temporally and spatially separated individual energy release episodes that can be difficult to resolve depending on the observing instrument. We present multi-wavelength imaging and spectroscopy observations of multiple electron acceleration episodes during a GOES B1.7-class two-ribbon flare on 2012 February 25, observed simultaneously with the Karl G. Jansky Very Large Array (VLA) at 1--2 GHz, the Reuven Ramatay High Energy Solar Spectroscopic Imager (RHESSI) in X-rays, and the Solar Dynamics Observatory in extreme ultraviolet (EUV). During the initial phase of the flare, five radio bursts were observed. A nonthermal X-ray source was seen co-temporal, but not co-spatial, with the first three radio bursts. Their radio spectra are interpreted as optically thick gyrosynchrotron emission. By fitting the radio spectra with a gyrosynchrotron model, we derive the magnetic field strength and nonthermal electron spectral parameters in each acceleration episode. Notably, the nonthermal parameters derived from X-rays differ considerably from the nonthermal parameters inferred from the radio. The observations are indicative of multiple, co-temporal acceleration episodes during the impulsive phase of a solar microflare. The X-ray and radio burst sources likely originate from separate electron distributions in different magnetic loops.