The role of filament activation in a solar eruption

TL;DR

This study analyzes a complex solar eruption event, revealing how filament destabilization and magnetic reconnection interplay to trigger flares and CMEs, emphasizing the active roles of multiple filaments in different eruption stages.

Contribution

The paper provides a detailed case study demonstrating the sequential roles of two filaments and magnetic field changes in a solar eruption, highlighting their distinct contributions to flare and CME development.

Findings

Filament destabilization triggers magnetic reconnection and flare ribbons.

Magnetic field reconfiguration leads to the eruption of a second filament.

The second filament's eruption causes a CME and plasma motions.

Abstract

Observations show that the mutual relationship between filament eruptions and solar flares cannot be described in terms of an unique scenario. In some cases, the eruption of a filament appears to trigger a flare, while in others the observations are more consistent with magnetic reconnection that produces both the flare observational signatures (e.g., ribbons, plasma jets, post-flare loops, etc.) and later the destabilization and eruption of a filament. We study an event which occurred in NOAA 8471, where a flare and the activation of (at least) two filaments were observed on 28 February 1999. By using imaging data acquired in the 1216, 1600, 171 and 195 \AA\ TRACE channels and by BBSO in the continnum and in H$\alpha$, a morphological study of the event is carried out. Using TRACE 1216 and 1600 \AA\ data, an estimate of the "pure" Ly$\alpha$ power is obtained. The extrapolation of the magnetic field lines is done using the SOHO/MDI magnetograms and assuming a potential field. The potential magnetic field extrapolation indicates that the field line connectivity changes after the flare. The event is triggered by the destabilization of a filament located between the two polarities of a $\delta$ spot. This destabilization involves the magnetic arcades of the active region and causes the eruption of a second filament, that gives rise to a CME and to plasma motions over a supergranular cell. We conclude that in this event the two filaments play an active and decisive role, albeit in different stages of the phenomenon, in fact the destabilization of one filament causes brightenings, reconnection and ribbons, while the second one, whose eruption is caused by the field reconfiguration resulting from the previous reconnection, undergoes the greatest changes and causes the CME.