Your search keyword '"Ch. Nutto"' showing total 2 results

1. Detection of vortex tubes in solar granulation from observations with Sunrise

Author

Oskar Steiner, Sami K. Solanki, Peter Barthol, V. Domingo, Reza Rezaei, J. A. Bonet Navarro, J. C. del Toro Iniesta, Achim Gandorfer, W. Schmidt, N. Bello González, M. Franz, M. Knölker, Ch. Nutto, and V. Martínez Pillet

Subjects

Convection, Physics, Vortex tube, Solar observatory, Computer simulation, Granule (solar physics), FOS: Physical sciences, Astronomy and Astrophysics, Astrophysics, Granulation, Astrophysics - Solar and Stellar Astrophysics, Space and Planetary Science, Substructure, Sunrise, Astrophysics::Solar and Stellar Astrophysics, Solar and Stellar Astrophysics (astro-ph.SR)

Abstract

We have investigated a time series of continuum intensity maps and corresponding Dopplergrams of granulation in a very quiet solar region at the disk center, recorded with the Imaging Magnetograph eXperiment (IMaX) on board the balloon-borne solar observatory Sunrise. We find that granules frequently show substructure in the form of lanes composed of a leading bright rim and a trailing dark edge, which move together from the boundary of a granule into the granule itself. We find strikingly similar events in synthesized intensity maps from an ab initio numerical simulation of solar surface convection. From cross sections through the computational domain of the simulation, we conclude that these `granular lanes' are the visible signature of (horizontally oriented) vortex tubes. The characteristic optical appearance of vortex tubes at the solar surface is explained. We propose that the observed vortex tubes may represent only the large-scale end of a hierarchy of vortex tubes existing near the solar surface., Astrophysical Journal Letters: Sunrise Special Issue, reveived 2010 June 16; accepted 2010 August 2

Published

2010

2. Modification of wave propagation and wave travel-time by the presence of magnetic fields in the solar network atmosphere

Author

Ch. Nutto, Markus Roth, Oskar Steiner, and W. Schaffenberger

Subjects

Physics, Wave propagation, Astronomy, Astronomy and Astrophysics, Context (language use), Astrophysics, Computational physics, Magnetic field, Space and Planetary Science, Speed of sound, Helioseismology, Phase velocity, Excitation, Equipartition theorem

Abstract

Context. Observations of waves at frequencies above the acoustic cut-off frequency have revealed vanishing wave travel-times in the vicinity of strong magnetic fields. This detection of apparently evanescent waves, instead of the expected propagating waves, has remained a riddle.Aims. We investigate the influence of a strong magnetic field on the propagation of magneto-acoustic waves in the atmosphere of the solar network. We test whether mode conversion effects can account for the shortening in wave travel-times between different heights in the solar atmosphere.Methods. We carry out numerical simulations of the complex magneto-atmosphere representing the solar magnetic network. In the simulation domain, we artificially excite high frequency waves whose wave travel-times between different height levels we then analyze.Results. The simulations demonstrate that the wave travel-time in the solar magneto-atmosphere is strongly influenced by mode conversion. In a layer enclosing the surface sheet defined by the set of points where the Alfven speed and the sound speed are equal, called the equipartition level, energy is partially transferred from the fast acoustic mode to the fast magnetic mode. Above the equipartition level, the fast magnetic mode is refracted due to the large gradient of the Alfven speed. The refractive wave path and the increasing phase speed of the fast mode inside the magnetic canopy significantly reduce the wave travel-time, provided that both observing levels are above the equipartition level. Conclusions. Mode conversion and the resulting excitation and propagation of fast magneto-acoustic waves is responsible for the observation of vanishing wave travel-times in the vicinity of strong magnetic fields. In particular, the wave propagation behavior of the fast mode above the equipartition level may mimic evanescent behavior. The present wave propagation experiments provide an explanation of vanishing wave travel-times as observed with multi-line high-cadence instruments.

Published

2012