Origins of Rolling, Twisting, and Non-radial Propagation of Eruptive Solar Events
Abstract
We demonstrate that major asymmetries in erupting filaments and CMEs, namely major twists and non-radial motions are typically related to the larger-scale ambient environment around eruptive events. Our analysis of prominence eruptions observed by the STEREO, SDO, and SOHO spacecraft shows that prominence spines retain, during the initial phases, the thin ribbon-like topology they had prior to the eruption. This topology allows bending, rolling, and twisting during the early phase of the eruption, but not before. The combined ascent and initial bending of the filament ribbon is non-radial in the same general direction as for the enveloping CME. However, the non-radial motion of the filament is greater than that of the CME. In considering the global magnetic environment around CMEs, as approximated by the Potential Field Source Surface (PFSS) model, we find that the non-radial propagation of both erupting filaments and associated CMEs is correlated with the presence of nearby coronal holes, which deflect the erupting plasma and embedded fields. In addition, CME and filament motions, respectively, are guided towards weaker field regions, namely null points existing at different heights in the overlying configuration. Due to the presence of the coronal hole, the large-scale forces acting on the CME may be asymmetric. We find that the CME propagates usually non-radially in the direction of least resistance, which is always away from the coronal hole. We demonstrate these results using both low- and high-latitude examples.
- Publication:
-
Solar Physics
- Pub Date:
- October 2013
- DOI:
- 10.1007/s11207-012-0194-3
- arXiv:
- arXiv:1211.1376
- Bibcode:
- 2013SoPh..287..391P
- Keywords:
-
- Coronal mass ejections;
- low coronal signatures;
- initiation and propagation;
- Magnetic fields;
- corona;
- Coronal holes;
- prominences;
- formation and evolution;
- Filaments;
- Astrophysics - Solar and Stellar Astrophysics
- E-Print:
- 26 pages, 20 figures, accepted in Solar Physics