Evolution of Photospheric Vector Magnetic Field Associated with Moving Flare Ribbons As Seen By GST

TL;DR

This study investigates how photospheric magnetic fields change in response to moving flare ribbons during a solar flare, revealing rapid and localized magnetic field variations linked to flare ribbon dynamics.

Contribution

It provides high-resolution observations showing the near-instantaneous response of photospheric magnetic fields to coronal magnetic reconnection during a flare.

Findings

Photospheric magnetic fields change at flare ribbon front arrival.

Horizontal fields increase and become more inclined during ribbon passage.

Vertical fields are enhanced near sunspot rotation centers.

Abstract

The photospheric response to solar flares, also known as coronal back reaction, is often observed as sudden flare-induced changes in vector magnetic field and sunspot motions. However, it remains obscure whether evolving flare ribbons, the flare signature closest to the photosphere, are accompanied by changes in vector magnetic field therein. Here we explore the relationship between the dynamics of flare ribbons in the chromosphere and variations of magnetic fields in the underlying photosphere, using high-resolution off-band H-alpha images and near-infrared vector magnetograms of the M6.5 flare on 2015 June 22 observed with the 1.6 m Goode Solar Telescope. We find that changes of photospheric fields occur at the arrival of the flare ribbon front, thus propagating analogously to flare ribbons. In general, the horizontal field increases and the field lines become more inclined to the surface. When ribbons sweep through regions that undergo a rotational motion, the fields transiently turn more vertical with decreased horizontal field and inclination angle, and then restore and/or become more horizontal than before the ribbon arrival. The ribbon propagation decelerates near the sunspot rotation center, where the vertical field becomes permanently enhanced. Similar magnetic field changes are discernible in magnetograms from the Helioseismic and Magnetic Imager (HMI), and an inward collapse of coronal magnetic fields is inferred from the time sequence of non-linear force-free field models extrapolated from HMI magnetograms. We conclude that photospheric fields respond nearly instantaneously to magnetic reconnection in the corona.