Astronomy and Astrophysics – Astrophysics
Scientific paper
2005-04-04
Astronomy and Astrophysics
Astrophysics
8 pages, 6 (low resolution) figures, Procs. of Conference Magnetic Fields in the Universe: from laboratory and stars to primor
Scientific paper
10.1063/1.2077221
Circulation-dominated solar dynamo models, which employ a helioseismic rotation profile and a fixed meridional flow, give a good approximation to the large scale solar magnetic phenomena, such as the 11-year cycle or the so called Hale's law of polarities. Nevertheless, the larger amplitude of the radial shear at the high latitudes makes the dynamo to produce a strong toroidal magnetic field at high latitudes, in contradiction with the observations of the sunspots (Sporer`s Law). A possible solution was proposed by Nandy and Choudhur (2002) in which a deep meridional flow can conduct the magnetic field inside of a stable layer (the radiative core) and then allow that it erupts just at lower latitudes. We have recently explored this hypothesis in a different approximation, using the magnetic buoyancy mechanism proposed by Dikpaty and Charbonneau (1999) and found that a deep meridional flow pushes the maximum of the toroidal magnetic field towards the solar equator, but, in contrast to Nandy and Choudhuri (2002), a second zone of maximum fields remains at the poles (Guerrero and Munoz (2004)). We here review these results and also discuss a new possible scenario where the tachocline has an ellipsoidal shape, following early helioseismologic observations Charbonneau et. al., (1999), and find that the modification of the geometry of the tachocline can lead to results which are in good agreement with observations and opens the possibility to explore in more detail, through the dynamo model, the place where the magnetic field could be really stored.
Dal Pino Elisabete M. de Gouveia
Guerrero G. A.
Munoz Diego J.
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