Deciphering Pre-solar-storm Features Of September-2017 Storm From Global And Local Dynamics

TL;DR

This study analyzes global and local magnetic features of solar active regions to improve forecasting of major solar flares, suggesting that minimum-phase storms are harder to predict than peak-phase storms, which can be forecast months in advance.

Contribution

It introduces a method combining global toroid patterns and local magnetic topology to forecast large solar flares with different lead times depending on the storm phase.

Findings

Minimum-phase storms are forecastable only hours in advance.

Peak-phase storms can be anticipated months ahead using global patterns.

Complex magnetic structures precede major flares, enabling short-term prediction.

Abstract

We investigate whether global toroid patterns and the local magnetic field topology of solar active region AR12673 together can hindcast occurrence of the biggest X-flare of solar cycle (SC)-24. Magnetic toroid patterns (narrow latitude-belts warped in longitude, in which active regions are tightly bound) derived from surface distributions of active regions, prior/during AR12673 emergence, reveal that the portions of the South-toroid containing AR12673 was not tipped-away from its north-toroid counterpart at that longitude, unlike the 2003 Halloween storms scenario. During the minimum-phase there were too few emergences to determine multi-mode longitudinal toroid patterns. A new emergence within AR12673 produced a complex/non-potential structure, which led to rapid build-up of helicity/winding that triggered the biggest X-flare of SC-24, suggesting that this minimum-phase storm can be anticipated several hours before its occurrence. However, global patterns and local dynamics for a peak-phase storm, such as that from AR11263, behaved like 2003 Halloween storms, producing the third biggest X-flare of SC-24. AR11263 was present at the longitude where the North/South toroids tipped-away from each other. While global toroid patterns indicate that pre-storm features can be forecast with a lead-time of a few months, its application on observational data can be complicated by complex interactions with turbulent flows. Complex/non-potential field structure development hours before the storm are necessary for short term prediction. We infer that minimum-phase storms cannot be forecast accurately more than a few hours ahead, while flare-prone active regions in peak-phase may be anticipated much earlier, possibly months ahead from global toroid patterns.