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Revealing the nature of magnetic shadows with numerical 3D-MHD simulations

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arxiv 1205.5308 v1 pith:PGT72EML submitted 2012-05-23 astro-ph.SR

Revealing the nature of magnetic shadows with numerical 3D-MHD simulations

classification astro-ph.SR
keywords magneticnetworkelementsmagneto-acousticpowershadowchromospheredifferent
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We investigate the interaction of magneto-acoustic waves with magnetic network elements with the aim of finding possible signatures of the magnetic shadow phenomenon in the vicinity of network elements. We carried out three-dimensional numerical simulations of magneto-acoustic wave propagation in a model solar atmosphere that is threaded by a complexly structured magnetic field, resembling that of a typical magnetic network element and of internetwork regions. High-frequency waves of 10 mHz are excited at the bottom of the simulation domain. On their way through the upper convection zone and through the photosphere and the chromosphere they become perturbed, refracted, and converted into different mode types. We applied a standard Fourier analysis to produce oscillatory power-maps of the line-of-sight velocity. In the power maps of the upper photosphere and the lower chromosphere, we clearly see the magnetic shadow: a seam of suppressed power surrounding the magnetic network elements. We demonstrate that this shadow is linked to the mode conversion process and that power maps at these height levels show the signature of three different magneto-acoustic wave modes.

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