Fast magnetoacoustic wave trains in magnetic funnels of the solar corona

Context. Fast magneto-acoustic waves are highly dispersive in waveguides, so they can generate quasi-periodic wave trains if a localised, impulsive driver is applied. Such wave trains have been observed in the solar corona and may be of use as a seismological tool since they depend upon the plasma s...

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Bibliographic Details
Published in:Astronomy and astrophysics (Berlin) 2013-12, Vol.560, p.np-np
Main Authors: Pascoe, D. J., Nakariakov, V. M., Kupriyanova, E. G.
Format: Article
Language:English
Subjects:
Computer simulation
Density
Funnels
magnetohydrodynamics (MHD)
Mathematical models
Solar corona
Sun: atmosphere
Sun: corona
Sun: magnetic fields
Sun: oscillations
Wave packets
Wave propagation
Waveguides
waves
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Summary:Context. Fast magneto-acoustic waves are highly dispersive in waveguides, so they can generate quasi-periodic wave trains if a localised, impulsive driver is applied. Such wave trains have been observed in the solar corona and may be of use as a seismological tool since they depend upon the plasma structuring perpendicular to the direction of propagation. Aims. We extend existing models of magnetoacoustic waveguides to consider the effects of an expanding magnetic field. The funnel geometry employed includes a field-aligned density structure. Methods. We performed 2D numerical simulations of impulsively generated fast magneto-acoustic perturbations. The effects of the density contrast ratio, density stratification, and spectral profile of the driver upon the excited wave trains were investigated. Results. The density structure acts as a dispersive waveguide for fast magneto-acoustic waves and generates a quasi-periodic wave train similar to previous models. The funnel geometry leads to generating additional wave trains that propagate outside the density structure. These newly discovered wave trains are formed by the leakage of transverse perturbations, but they propagate upwards owing to the refraction caused by the magnetic funnel. Conclusions. The results of our funnel model may be applicable to wave trains observed propagating in the solar corona. They demonstrate similar properties to those found in our simulations.
ISSN:0004-6361
1432-0746
DOI:10.1051/0004-6361/201322678