Bibcode
Rial, S.; Arregui, I.; Terradas, J.; Oliver, R.; Ballester, J. L.
Referencia bibliográfica
The Astrophysical Journal, Volume 713, Issue 1, pp. 651-661 (2010).
Fecha de publicación:
4
2010
Revista
Número de citas
7
Número de citas referidas
7
Descripción
We numerically investigate the excitation and temporal evolution of
oscillations in a two-dimensional coronal arcade by including the
three-dimensional propagation of perturbations. The time evolution of
impulsively generated perturbations is studied by solving the linear,
ideal magnetohydrodynamic (MHD) equations in the zero-β
approximation. As we neglect gas pressure, the slow mode is absent and
therefore only coupled fast MHD and Alfvén modes remain. Two
types of numerical experiments are performed. First, the resonant wave
energy transfer between a fast normal mode of the system and local
Alfvén waves is analyzed. It is seen how, because of resonant
coupling, the fast wave with global character transfers its energy to
Alfvénic oscillations localized around a particular magnetic
surface within the arcade, thus producing the damping of the initial
fast MHD mode. Second, the time evolution of a localized impulsive
excitation, trying to mimic a nearby coronal disturbance, is considered.
In this case, the generated fast wavefront leaves its energy on several
magnetic surfaces within the arcade. The system is therefore able to
trap energy in the form of Alfvénic oscillations, even in the
absence of a density enhancement such as that of a coronal loop. These
local oscillations are subsequently phase-mixed to smaller spatial
scales. The amount of wave energy trapped by the system via wave energy
conversion strongly depends on the wavelength of perturbations in the
perpendicular direction, but is almost independent from the ratio of the
magnetic to density scale heights.