Radio, X-ray, and EUV signatures of internal and external reconnection of an erupting flux rope

TL;DR

This study combines multi-instrument EUV, X-ray, and radio observations to analyze the magnetic reconnection processes during a solar flux rope eruption, revealing detailed signatures of internal and external reconnection events.

Contribution

It provides new insights into the multi-wavelength signatures and magnetic reconnection geometry of erupting flux ropes using coordinated observations from multiple space and ground-based instruments.

Findings

Identification of hot loops indicating arcade-to-rope reconnection

Detection of helical structures and radio burst signatures of beam acceleration

Observation of complex radio burst tangle associated with magnetic untwisting

Abstract

We analyse imaging (EUV, X-ray) and spectral (radio, X-ray) data obtained by ground based and space instruments on board space missions both on Earth (Fermi, Hinode, Solar Dynamics Observatory) and solar orbit (Solar Orbiter, STEREO-A), which provide a multi-directional view on the same event. The combination of EUV and X-ray images and X-ray spectra allowed us to identify hot loops in the vicinity of the filament before its eruption. We interpreted their interaction with the rising filament as a signature of an arcade-to-rope reconnection geometry. The subsequent EUV brightening within the filament revealed helical structure of the erupting rope. We explained co-temporal radio slowly positively drifting bursts as a result of beam acceleration within the magnetic rope and propagation along the helical structure. Corresponding X-ray spectra were consistent with a thermal origin. The filament rising was accompanied by co-temporal normal and reverse drift type III radio bursts. We interpreted them as a signature of a reconnection event and estimated electron density at the reconnection site. Further untwisting of the helical structure led to formation of a quasi-circular EUV structure seen from Earth and STEREO-A. Its occurrence was co-temporal with a unique tangle of radio U- and inverse U-bursts. We proposed that several accelerated beams propagate within that complex structure and generate the burst tangle. During the start of the flare hard X-ray emission was concentrated near the filament leg only suggesting predominant propagation of the beams towards its rooting. We collected multi-wavelength observations indicating interaction of the erupting magnetic flux rope with the overlying arcade and internal magnetic reconnection inside the rising flux rope.