What is Unusual about the Third Largest Geomagnetic Storm of Solar Cycle 24?

TL;DR

This paper investigates the causes of the third largest geomagnetic storm of solar cycle 24, highlighting the roles of prolonged CME acceleration, complex magnetic rotation, and high-density magnetic cloud in storm intensity.

Contribution

It provides a detailed analysis of the solar and interplanetary factors contributing to a major geomagnetic storm, emphasizing the importance of CME acceleration and density structure.

Findings

Prolonged CME acceleration correlates with storm intensity.

High-density magnetic clouds enhance ring current energy.

Complex magnetic rotation influences storm development.

Abstract

We report on the solar and interplanetary (IP) causes of the third largest geomagnetic storm (2018 August 26) in solar cycle 24. The underlying coronal mass ejection (CME) originating from a quiescent filament region becomes a 440 km/s magnetic cloud (MC) at 1 au after ~5 days. The prolonged CME acceleration (for about 24 hrs) coincides with the time profiles of the post-eruption arcade intensity and reconnected flux. Chen et al. (2019) obtain lower speed since they assumed that the CME does not accelerate after about 12 hrs. The presence of multiple coronal holes near the filament channel and the high-speed wind from them seem to have the combined effect of producing complex rotation in the corona and IP medium resulting in a high-inclination MC. The Dst time profile in the main phase steepens significantly (rapid increase in storm intensity) coincident with the density increase (prominence material) in the second half of the MC. Simulations using the Comprehensive Inner Magnetosphere-Ionosphere (CIMI) model shows that a higher ring current energy results from larger dynamic pressure in MCs. Furthermore, the Dst index is highly correlated with the main-phase time integral of the ring current injection that includes density, consistent with the simulations. A complex temporal structure develops in the storm main phase if the underlying MC has a complex density structure during intervals of southward interplanetary magnetic field. We conclude that the high intensity of the storm results from the prolonged CME acceleration, complex rotation, and the high density in the 1-au MC.