Abstract
The size distribution of sunspots provides key information about the generation and emergence processes of the solar magnetic field. Previous studies of size distribution have primarily focused on either the whole group or individual spot areas. In this paper we investigate the organisation of spot areas within sunspot groups. In particular, we analysed the ratio (R) of the area of the biggest spot (Abig_spot) inside a group, to the total area of that group (Agroup). We used sunspot observations from Kislovodsk, Pulkovo, and Debrecen observatories, together covering solar cycles 17–24. We find that at the time when the group area reaches its maximum, the single biggest spot in a group typically occupies about 60% of the group area. For half of all groups, R lies in the range between roughly 50% and 70%. We also find R to change with Agroup, such that R reaches a maximum of about 0.65 for groups with Agroup ≈ 200 μHem and then remains at about 0.6 for larger groups. Our findings imply a scale-invariant emergence pattern, providing an observational constraint on the emergence process. Furthermore, extrapolation of our results to larger sunspot groups may have a bearing on the giant unresolved starspot features found in Doppler images of highly active Sun-like stars. Our results suggest that such giant features are composed of multiple spots, with the largest spot occupying roughly 55–75% of the total group area (i.e., the area of the giant starspots seen in Doppler images).
Highlights
The magnetic field of the Sun, the driving force of its activity and variability, is generated in its interior by a dynamo action and emerges at the surface as bipolar regions
In this paper we investigate the organisation of spot areas within sunspot groups
Our results suggest that such giant features are composed of multiple spots, with the largest spot occupying roughly 55–75% of the total group area
Summary
The magnetic field of the Sun, the driving force of its activity and variability, is generated in its interior by a dynamo action and emerges at the surface as bipolar regions. Using individual spot area measurements from the Kislovodsk Mountain Station and group areas from RGO, Solar Observing Optical Network (SOON), Pulkovo, and Kislovodsk, Nagovitsyn et al (2012) and Muñoz-Jaramillo et al (2015) showed that the overall size distribution was better characterised by two separate distribution functions respectively for small and big groups or spots. They argued that such a bi-modal size distribution could possibly imply a more complex process of spot formation, for example driven by small-scale and global dynamos in parallel (Nagovitsyn & Pevtsov 2016).
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