Magnetic properties of a long-lived sunspot - Vertical magnetic field at the umbral boundary

TL;DR

This study examines the stability of the vertical magnetic field at the umbral boundary of a long-lived sunspot, finding it remains constant during the sunspot's stable phase, unlike the magnetic field strength which varies.

Contribution

It demonstrates that the vertical magnetic field at the umbral boundary remains constant during a sunspot's stable phase, supporting the idea that it defines the umbral boundary more reliably than magnetic field strength.

Findings

Vertical magnetic field at the umbral boundary remains constant during stable phase.

Contours of fixed magnetic field strength do not outline the umbral boundary.

Compensating for formation height reduces variations in magnetic field measurements.

Abstract

Context. In a recent statistical study of sunspots in 79 active regions, the vertical magnetic field component $B_\text{ver}$ averaged along the umbral boundary is found to be independent of sunspot size. The authors of that study conclude that the absolute value of $B_\text{ver}$ at the umbral boundary is the same for all spots. Aims. We investigate the temporal evolution of $B_\text{ver}$ averaged along the umbral boundary of one long-lived sunspot during its stable phase. Methods. We analysed data from the HMI instrument on-board SDO. Contours of continuum intensity at $I_\text{c}=0.5I_\text{qs}$, whereby $I_\text{qs}$ refers to the average over the quiet sun areas, are used to extract the magnetic field along the umbral boundary. Projection effects due to different formation heights of the Fe I 617.3 nm line and continuum are taken into account. To avoid limb artefacts, the spot is only analysed for heliocentric angles smaller than $60^{\circ}$. Results. During the first disc passage, NOAA AR 11591, $B_\text{ver}$ remains constant at 1693 G with a root-mean-square deviation of 15 G, whereas the magnetic field strength varies substantially (mean 2171 G, rms of 48 G) and shows a long term variation. Compensating for formation height has little influence on the mean value along each contour, but reduces the variations along the contour when away from disc centre, yielding a better match between the contours of $B_\text{ver}=1693$ G and $I_\text{c}=0.5I_\text{qs}$. Conclusions. During the disc passage of a stable sunspot, its umbral boundary can equivalently be defined by using the continuum intensity $I_\text{c}$ or the vertical magnetic field component $B_\text{ver}$. Contours of fixed magnetic field strength fail to outline the umbral boundary.