Rotation of flux ropes in the low corona

TL;DR

This paper investigates the rotation of solar filaments and flux ropes in the low corona, demonstrating that significant rotation occurs early and affects space weather predictions, with case studies supported by simulations.

Contribution

It provides new insights into the mechanisms of flux rope rotation in the low corona and highlights the importance of early rotation in space weather forecasting.

Findings

CME rotation in the low corona can be significant and affect predictions.

Numerical simulations confirm observed filament rotations.

Low coronal rotation may lead to erroneous space weather forecasts.

Abstract

Eruptions of filaments are defined by different parameters, specially, sigmoid handedness and direction of the eruption, which are important parameters for forecasting the geoeffectiveness of consequent interplanetary coronal mass ejection (ICME) or magnetic cloud. Solar filaments often exhibit rotation and deflection during eruptions, which would significantly affect the geoeffectiveness of the coronal mass ejections (CMEs). Therefore, understanding the mechanisms that lead to such lateral displacement of filaments is a great concern to space weather forecasting. Two case studies are discussed. Firstly, the events of September 8 and September 10 2014, were analyzed from the Sun to the Earth. The numerical heliospheric simulation EUHFORIA shows that the handedness of the EUV sigmoid deduced from coronagraph observations was different from the tilt of the ICME at 1~au, suggesting a rotation of the CME in the low corona. A potential undetected low coronal rotation led to erroneous space weather prediction. The second event concerns a filament observed on August 20 2021, which underwent a rotation of 73 degrees during its eruption, implying a significant lateral drifting of the filament material. A data-constrained magnetohydrodynamic (MHD) simulation confirms such a rotation. These two studies reinforce the idea that CMEs are subjected to more significant rotation and deflection in the low corona than during their journey in the heliosphere.