Distributed Electric Currents in Solar Active Regions

TL;DR

This study analyzes magnetic fields and electric currents in solar active regions, revealing large-scale vortex structures and a correlation between current variations and flare activity, enhancing understanding of solar magnetic phenomena.

Contribution

It uncovers the existence of large-scale distributed electric currents in active regions and links their variations to flare activity, providing new insights into solar magnetic structures.

Findings

Electric currents are well balanced within active regions.

Large-scale vortex structures of magnetic fields are observed around sunspots.

Flare activity correlates with slow variations in distributed electric currents.

Abstract

Using magnetographic data provided by the Helioseismic and Magnetic Imager on board the Solar Dynamics Observatory, we analyzed the structure of magnetic fields and vertical electric currents in six active regions (ARs) with different level of flare activity. We found that electric currents are well balanced over the entire AR: for all of them the current imbalance is below 0.1%, which means that any current system is closed within an AR. Decomposition of the transverse magnetic field vector into two components allowed us to reveal the existence of large-scale vortex structures of the azimuthal magnetic field component around main sunspots of ARs. In each AR, we found a large-scale electric current system occupying a vast area of an AR, which we call distributed electric current. For ARs obeying the Hale polarity law and the hemispheric helicity sign rule, the distributed current is directed upward in the leading part of an AR and it appears to be closing back to the photosphere in the following part of an AR through the corona and chromosphere. Our analysis of the time variations of the magnitude of the distributed electric currents showed that low-flaring ARs exhibit small variations of the distributed currents in the range of $\pm 20 \times 10^{12}$ A, whereas the highly flaring ARs exhibited significant slow variations of the distributed currents in the range of $30-95 \times 10^{12}$ A. Intervals of the enhanced flaring appear to be co-temporal with smooth enhancements of the distributed electric current.