Microwave Study of a Solar Circular Ribbon Flare

TL;DR

This study analyzes microwave and UV data of a solar circular ribbon flare, revealing preflare thermal activity, magnetic breakout signatures, and oscillatory phenomena linked to the eruption process in a fan-spine magnetic structure.

Contribution

It provides new insights into the microwave signatures and magnetic dynamics of a circular ribbon flare, highlighting the breakout process and oscillation transfer mechanisms.

Findings

Preflare thermal preheating indicated by 17 GHz flux increase.

Polarization sign reversal suggests magnetic breakout in fan-spine structure.

Quasi-periodic oscillations observed before and after eruption, indicating wave transfer.

Abstract

A circular ribbon flare SOL2014-12-17T04:51 is studied using the 17/34 GHz maps from the Nobeyama Radioheliograph (NoRH) along with (E)UV and magnetic data from the Solar Dynamics Observatory (SDO). We report the following three findings as important features of the microwave CRF. (1) The first preflare activation comes in the form of a gradual increase of the 17 GHz flux without a counterpart at 34 GHz, which indicates thermal preheating. The first sign of nonthermal activity occurs in the form of stepwise flux increases at both 17 and 34 GHz about 4 min before the impulsive phase. (2) Until the impulsive phase, the microwave emission over the entire active region is in a single polarization state matching the magnetic polarity of the surrounding fields. During and after the impulsive phase, the sign of the 17 GHz polarization state reverses in the core region, which implies a magnetic breakout--type eruption in a fan-spine magnetic structure. (3) The 17 GHz flux around the time of the eruption shows quasi-periodic variations with periods of 1--2 min. The pre-eruption oscillation is more obvious in total intensity at one end of the flare loop, and the post-eruption oscillation, more obvious in the polarized intensity at a region near the inner spine. We interpret this transition as the transfer of oscillatory power from kink mode oscillation to torsional Alfv\'en waves propagating along the spine field after the eruption. We argue that these three processes are inter-related and indicate a breakout process in a fan-spine structure.