Solar Eruption and Local Magnetic Parameters

TL;DR

This study examines whether local magnetic parameters or the overall magnetic structure better predict solar eruptions, using SDO observations and NLFFF modeling, and finds that global factors and dynamic processes play a crucial role.

Contribution

It highlights the importance of global magnetic properties and dynamic factors over local parameters in determining solar eruption timing and behavior.

Findings

High magnetic twist and decay index correlate with violent eruptions.

Eruption timing is influenced by ongoing heating and plasma flows.

Global magnetic structure affects eruption onset more than local parameters.

Abstract

It is now a common practice to use local magnetic parameters such as magnetic decay index for explaining solar eruptions from active regions, but there can be an alternative view that the global properties of the source region should be counted as a more important factor. We discuss this issue based on {\it Solar Dynamics Observatory} (SDO) observations of the three successive eruptions within 1.5 hours from the NOAA active region 11444 and the magnetic parameters calculated using the nonlinear force-free field (NLFFF) model. Two violent eruptions occurred in the regions with relatively high magnetic twist number (0.5--1.5) and high decay index (0.9--1.1) at the nominal height of the filament (12$''$) and otherwise a mild eruption occurred, which supports the local parameter paradigm. Our main point is that the time sequence of the eruptions did not go with these parameters. It is argued that an additional factor, in the form of stabilizing force, should operate to determine the onset of the first eruption and temporal behaviors of subsequent eruptions. As supporting evidence, we report that the heating and fast plasma flow continuing for a timescale of an hour was the direct cause for the first eruption, and that the unidirectional propagation of the disturbance determined the timing of subsequent eruptions. Both of these factors are associated with the overall magnetic structure rather than local magnetic properties of the active region.