Observation of "Topological" Microflares in the Solar Atmosphere

TL;DR

This paper reports the first clear observational evidence of topological microflares in the solar atmosphere, linked to magnetic reconnection triggered by specific magnetic source configurations, confirming a long-standing theoretical model.

Contribution

It provides observational validation of the topological trigger model for solar microflares, previously only theorized, by identifying characteristic features and magnetic configurations.

Findings

Observation of bright loops connecting sunspots with unusual properties.

Identification of rapid flare expansion consistent with topological trigger predictions.

Correlation between magnetic source arrangements and flare initiation.

Abstract

We report on observation of the unusual kind of solar microflares, presumably associated with the so-called "topological trigger" of magnetic reconnection, which was theoretically suggested long time ago by Gorbachev et al. (Sov. Ast. 1988, v.32, p.308) but has not been clearly identified so far by observations. As can be seen in pictures by Hinode SOT in CaII line, there may be a bright loop connecting two sunspots, which looks at the first sight just as a magnetic field line connecting the opposite poles. However, a closer inspection of SDO HMI magnetograms shows that the respective arc is anchored in the regions of the same polarity near the sunspot boundaries. Yet another peculiar feature is that the arc flashes almost instantly as a thin strip and then begins to expand and decay, while the typical chromospheric flares in CaII line are much wider and propagate progressively in space. A qualitative explanation of the unusual flare can be given by the above-mentioned model of topological trigger. Namely, there are such configurations of the magnetic sources on the surface of photosphere that their tiny displacements result in the formation and fast motion of a 3D null point along the arc located well above the plane of the sources. So, such a null point can quickly ignite a magnetic reconnection along the entire its trajectory. Pictorially, this can be presented as flipping the so-called two-dome magnetic-field structure (which is just the reason why such mechanism was called topological). The most important prerequisite for the development of topological instability in the two-dome structure is a cruciform arrangement of the magnetic sources in its base, and this condition is really satisfied in the case under consideration.