Superstrong magnetic fields in sunspot bipolar light bridges

TL;DR

This study reveals that bipolar light bridges in sunspots frequently host magnetic fields exceeding 4.5 kG, indicating a distinct magnetoconvection regime and expanding understanding of magnetic field strengths in sunspot features.

Contribution

It provides the largest spectropolarimetric analysis of bipolar light bridges, demonstrating that strong magnetic fields are common and characterizing their unique properties.

Findings

All bipolar light bridges analyzed have magnetic fields >4.5 kG.

Fields decrease faster with height than in umbrae and penumbrae.

BLBs are a distinct population with high brightness despite strong fields.

Abstract

Recent solar observations of bipolar light bridges (BLBs) in sunspots have, in a few individual cases, revealed magnetic fields up to 8.2 kG, which is at least twice as strong as typical values measured in sunspot umbrae. However, the small number of such observations hinted that such strong fields in these bright photospheric features that separate two opposite-polarity umbrae, are a rare phenomenon. We determine the field strength in a large sample of BLBs with the aim of establishing how prevalent such strong fields are in BLBs. We apply a state-of-the-art inversion technique that accounts for the degradation of the data by the intrinsic point spread function of the telescope, to the so far largest set of spectropolarimetric observations, by Hinode/Solar Optical Telescope spectropolarimeter, of sunspots containing BLBs. We identified 98 individual BLBs within 51 distinct sunspot groups. Since 66.3% of the BLBs were observed multiple times, a total of 630 spectropolarimetric scans of these 98 BLBs were analysed. All analysed BLBs contain magnetic fields stronger than 4.5 kG at unit optical depth. The field strengths decrease faster with height than the fields in umbrae and penumbrae. BLBs display a unique continuum intensity and field strength combination, forming a population well separated from umbrae and the penumbrae. The high brightness of BLBs in spite of their very strong magnetic fields points to the presence of a so far largely unexplored regime of magnetoconvection.