6533b7d7fe1ef96bd1268fa1
RESEARCH PRODUCT
Modeling Non-Confined Coronal Flares: Dynamics and X-Ray Diagnostics
Giovanni PeresFabrizio BocchinoFabio Realesubject
PhysicsAstrophysics::High Energy Astrophysical PhenomenaAstrophysics (astro-ph)Magnetic confinement fusionFOS: Physical sciencesAstronomy and AstrophysicsPlasmaAstrophysicsLight curveAstrophysicsCoronaSpectral lineMagnetic fieldlaw.inventionSpace and Planetary SciencelawChromosphereFlaredescription
Long-lasting, intense, stellar X-ray flares may approach conditions of breaking magnetic confinement and evolving in open space. We explore this hypothesis with hydrodynamic simulations of flares occurring in a non-confined corona: model flares are triggered by a transient impulsive heating injected in a plane-parallel stratified corona. The plasma evolution is described by means of a numerical 2-D model in cylindrical geometry R,Z. We explore the space of fundamental parameters. As a reference model, we consider a flare triggered by a heating pulse that would cause a 20 MK flare if delivered in a 40000 km long closed loop. The modeled plasma evolution is described. The X-ray emission, spectra and light curves at the ASCA/SIS focal plan, and in two intense X-ray lines (Mg XI at 9.169 A and Fe XXI at 128.752 A), have been synthesized from the models. The results are discussed and compared to features of confined events, and scaling laws are derived. The light curves invariably show a very rapid rise, a constant phase as long as the constant heating is on, and then a very fast decay, on time scales of few seconds, followed by a more gradual one (few minutes). We show that this evolution of the emission, and especially the fast decay, together with other potentially observable effects, are intrinsic to the assumption of non-confinement. Their lack indicates that observed long-lasting stellar X-ray flares should involve plasma strongly confined by magnetic fields.
year | journal | country | edition | language |
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2001-12-14 |