Searching for evidence of subchromospheric magnetic reconnection on the Sun

TL;DR

This study investigates potential subchromospheric magnetic reconnection on the Sun by combining 3D visualization with observations of the inverse-FIP effect, providing indirect evidence of reconnection sites linked to plasma composition anomalies.

Contribution

It introduces a novel approach combining visualization and observational data to identify potential reconnection sites associated with the inverse-FIP effect in solar active regions.

Findings

Detected episodic heating and reconnection outflows near light bridges.

Observed small antiparallel magnetic fields supporting reconnection hypotheses.

Provided indirect evidence of reconnection below the chromospheric fractionation layer.

Abstract

Within the coronae of stars, abundances of those elements with low first ionization potential (FIP) often differ from their photospheric values. The coronae of the Sun and solar-type stars mostly show enhancements of low-FIP elements (the FIP effect) while more active stars such as M dwarfs have coronae generally characterized by the inverse-FIP (I-FIP) effect. Highly localized regions of I-FIP effect solar plasma have been observed by Hinode/EIS in a number of highly complex active regions, usually around strong light bridges of the umbrae of coalescing/merging sunspots. These observations can be interpreted in the context of the ponderomotive force fractionation model which predicts that plasma with I-FIP effect composition is created by the refraction of waves coming from below the plasma fractionation region in the chromosphere. A plausible source of these waves is thought to be reconnection in the (high-plasma \b{eta}) subchromospheric magnetic field. In this study, we use the 3D visualization technique of Chintzoglou & Zhang (2013) combined with observations of localized I-FIP effect in the corona of AR 11504 to identify potential sites of such reconnection and its possible consequences in the solar atmosphere. We found subtle signatures of episodic heating and reconnection outflows in the expected places, in between magnetic flux tubes forming a light bridge, within the photosphere of the active region. Furthermore, on either side of the light bridge, we observed small antiparallel horizontal magnetic field components supporting the possibility of reconnection occuring where we observe I-FIP plasma. When taken together with the I-FIP effect observations, these subtle signatures provide a compelling case for indirect observational evidence of reconnection below the fractionation layer of the chromosphere, however, direct evidence remains elusive.