Akademik Veri Yönetim Sistemi
Solar Physics, cilt.301, sa.3, 2026 (SCI-Expanded, Scopus)
Sunspot groups often emerge in spatial–temporal clusters, known as nests or complexes of activity. Quantifying how frequently such nesting occurs is important for understanding the organisation and recurrence of solar magnetic fields. We introduce an automated approach based on kernel density estimation and DBSCAN clustering to identify nests in the longitude–time domain and to measure the fraction of sunspot groups that belong to them. The method combines a smooth representation of emergence patterns with a density-based clustering procedure, validated using synthetic solar-like cycles and corrected for variations in data density. We apply this method to 151 years of sunspot-group observations from the Royal Greenwich Observatory Photoheliographic Results (RGO, 1874 – 1976) and Kislovodsk Mountain Astronomical Station (KMAS, 1955 – 2025) catalogues. Across all cycles and latitude bands, the mean nesting degree is 〈D〉=0.61±0.12, implying that about 60 percent all sunspot groups emerge within nests. Nesting is strongest at mid-latitudes (10∘ – 20∘), and results from the two independent datasets agree in the period of overlap. The nesting degree significantly correlates with the solar activity level, with the correlation strengthening when small groups are excluded. The characteristic inter-nest spacing contracts from ∼ 200 – 500 Mm at low activity to ∼ 60 – 100 Mm at solar maximum, approaching typical sunspot-group dimensions. The identified nests range from compact clusters to long-lived, drifting structures, offering new quantitative constraints on the persistence and organisation of solar magnetic activity.