Characterizing the Umbral Magnetic Knots of δ-Sunspots

Abstract

Delta (δ)-spots are active regions (ARs) in which positive and negative umbrae share a penumbra. They are known to be the source of strong flares. We introduce a new quantity, the degree of δ (Doδ), to measure the fraction of umbral flux participating in the δ-configuration and to isolate the dynamics of the magnetic knot, i.e. adjacent umbrae in the δ-configuration. Using Helioseismic and Magnetic Imager data, we analyze 19 δ-spots and 11 β-spots in detail, and 120 δ-spots in less detail. We find that δ-regions are not in a δ-configuration for the entire time but spend 55\% of their observed time as δ-spots with an average, maximum Doδ of 72\%. Compared to β-spots, δ-spots have 2.6× the maximum umbral flux, 1.9× the flux emergence rate, 2.6× the rotation, and 72× the flare energy. On average, the magnetic knots rotate 17 day-1 while the β-spots rotate 2 day-1. Approximately 72\% of the magnetic knots present anti-Hale or anti-Joy tilts, contrasting starkly with only 9\% of the β-spots. A positive correlation exists between φDoδ and the flare energy emitted by that region. The δ-spots obey the hemispheric current helicity rule 64\% of the time. 84\% of the δ-spots are formed by single flux emergence events and 58\% have a quadrupolar magnetic configuration. The δ-spot characteristics are consistent with the formation mechanism signatures as follows: 42\% with the kink instability or Sigma effect, 32\% with multi-segment buoyancy, 16\% with collisions and two active regions that are unclassified but consistent with a rising O-ring.