Active Region Photospheric Magnetic Properties Derived from Line-of-sight and Radial Fields

TL;DR

This study compares line-of-sight and radial magnetic field measurements in solar active regions, revealing differences in property values, correlations, and flare rates, with implications for better flare prediction methods.

Contribution

It demonstrates that using the radial magnetic field component provides more independent and potentially more accurate magnetic properties for flare prediction.

Findings

Radial field results in higher property values and lower correlations.

Flaring rates increase with property values, peaking at specific spectral indices.

Radial field measurements may improve flare forecasting, especially for regions away from the solar center.

Abstract

The effect of using two representations of the normal-to-surface magnetic field to calculate photospheric measures that are related to active region (AR) potential for flaring is presented. Several AR properties were computed using line-of-sight ($B_{\rm los}$) and spherical-radial ($B_{r}$) magnetograms from the Space-weather HMI Active Region Patch (SHARP) products of the \emph{Solar Dynamics Observatory}, characterizing the presence and features of magnetic polarity inversion lines, fractality, and magnetic connectivity of the AR photospheric field. The data analyzed corresponds to $\approx$ 4,000 AR observations, achieved by randomly selecting 25 % of days between September 2012 and May 2016 for analysis at 6-hr cadence. Results from this statistical study include: i) the $B_{r}$ component results in a slight upwards shift of property values in a manner consistent with a field-strength underestimation by the $B_{\rm los}$ component; ii) using the $B_{r}$ component results in significantly lower inter-property correlation in one-third of the cases, implying more independent information about the state of the AR photospheric magnetic field; iii) flaring rates for each property vary between the field components in a manner consistent with the differences in property-value ranges resulting from the components; iv) flaring rates generally increase for higher values of properties, except Fourier spectral power index that has flare rates peaking around a value of $5/3$. These findings indicate that there may be advantages in using $B_{r}$ rather than $B_{\rm los}$ in calculating flare-related AR magnetic properties, especially for regions located far from central meridian.