An Empirical 3D Model of the Large-scale Coronal Structure Based on the Distribution of Prominences on the Solar Disk

Despite the wealth of solar data currently available, the explicit connection between coronal streamers and features on the solar disk remains unresolved. An empirical three-dimensional model, which reproduces the evolution of the large-scale coronal structure starting from the solar surface, is pre...

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Bibliographic Details
Published inarXiv.org
Main Authors Morgan, Huw, S Rifai Habbal
Format Paper
LanguageEnglish
Published Ithaca Cornell University Library, arXiv.org 06.10.2006
Subjects
Current sheets
Evolution
Filaments
Prominences
Solar activity
Solar corona
Solar cycle
Solar physics
Solar rotation
Solar surface
Three dimensional models
White light
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Summary:Despite the wealth of solar data currently available, the explicit connection between coronal streamers and features on the solar disk remains unresolved. An empirical three-dimensional model, which reproduces the evolution of the large-scale coronal structure starting from the solar surface, is presented. The model is based on the view that the source of the large-scale coronal structure, namely streamers, is a consequence of the evolution of twisted sheet-like structures originating from prominences (or, equivalently, filaments) at the base of the corona. The high-density sheets evolve and merge with height into a final radial configuration constrained by the oberved position of streamers stalks higher up in the corona. The observational constraints are provided by white light observations from the LASCO/C2 data during the declining phase of solar activity, spanning the end of Carrington Rotation (CR) 2005 and the start of CR 2006, i.e. July-August 2003, and the position of filaments from the corresponding H\(\alpha\) synoptic maps of the Paris-Meudon Observatory. The 3D model thus derived yields a reasonable agreement with the observed large-scale coronal structure, in particular the shape of large helmet streamers. These results give confidence in the underlying assumption that large helmet streamers can be the result of the convergence of two or more sheet-like structures originating from a distribution of prominences on the solar disk. The model supports the view that streamers, during that time of the solar cycle, are often associated with multiple current sheets.
ISSN:2331-8422
DOI:10.48550/arxiv.0610219