About: Magnetohydrodynamic simulations of the ejection of a magnetic flux rope

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Attributs	Valeurs
type	work Article
Is Part Of	http://hub.abes.fr/edp/periodical/aa/2013/volume_554/issue_2013/w
Subject	magnetohydrodynamics (MHD) The Sun magnetic fields Sun: corona Sun: coronal mass ejections
Title	Magnetohydrodynamic simulations of the ejection of a magnetic flux rope
Date	2013-01-01(xsd:dateTime)
has manifestation of work	http://hub.abes.fr/edp/periodical/aa/2013/volume_554/issue_2013/aa20947-12/m/print http://hub.abes.fr/edp/periodical/aa/2013/volume_554/issue_2013/aa20947-12/m/web
related by	http://hub.abes.fr/edp/periodical/aa/2013/volume_554/issue_2013/aa20947-12/authorship/3 http://hub.abes.fr/edp/periodical/aa/2013/volume_554/issue_2013/aa20947-12/authorship/1 http://hub.abes.fr/edp/periodical/aa/2013/volume_554/issue_2013/aa20947-12/authorship/2
Author	Poedts S. Mackay D. H. Pagano, P.
Abstract	Context. Coronal mass ejections (CME’s) are one of the most violent phenomena found on the Sun. One model to explain their occurrence is the flux rope ejection model. In this model, magnetic flux ropes form slowly over time periods of days to weeks. They then lose equilibrium and are ejected from the solar corona over a few hours. The contrasting time scales of formation and ejection pose a serious problem for numerical simulations. Aims. We simulate the whole life span of a flux rope from slow formation to rapid ejection and investigate whether magnetic flux ropes formed from a continuous magnetic field distribution, during a quasi-static evolution, can erupt to produce a CME. Methods. To model the full life span of magnetic flux ropes we couple two models. The global non-linear force-free field (GNLFFF) evolution model is used to follow the quasi-static formation of a flux rope. The MHD code ARMVAC is used to simulate the production of a CME through the loss of equilibrium and ejection of this flux rope. Results. We show that the two distinct models may be successfully coupled and that the flux rope is ejected out of our simulation box, where the outer boundary is placed at 2.5 R⊙. The plasma expelled during the flux rope ejection travels outward at a speed of 100 km s -1, which is consistent with the observed speed of CMEs in the low corona. Conclusions. Our work shows that flux ropes formed in the GNLFFF can lead to the ejection of a mass loaded magnetic flux rope in full MHD simulations. Coupling the two distinct models opens up a new avenue of research to investigate phenomena where different phases of their evolution occur on drastically different time scales.
article type	research-article
publisher identifier	aa20947-12
Date Copyrighted	2013-01-01(xsd:dateTime)
Rights	© ESO, 2013
Rights Holder	ESO
is part of this journal	Astronomy & Astrophysics
is primary topic of	http://hub.abes.fr/edp/periodical/aa/2013/volume_554/issue_2013/aa20947-12/w/record

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