Bibcode
Moreno-Insertis, F.
Referencia bibliográfica
Solar Magnetic Fields, ed. V. Hansteen, (Oslo: University of Oslo), p. 3 -30
Fecha de publicación:
0
1997
Número de citas
1
Número de citas referidas
1
Descripción
The studies of the emergence of magnetic flux across the convection zone
show how the individual magnetic tubes rise toward the surface at the
same time remaining anchored at the interface between the convection
zone and the radiative interior. A number of recent numerical
simulations, in particular, reproduce several observed features of the
resulting active regions (e.g., tilt angles, preceding-following
asymmetries, etc). These simulations are based on the thin flux tube
approximation, which simplifies the magnetic ropes as a one-dimensional
continuum. The thin flux tube approximation has provided valuable
insights concerning the rise of the magnetic tubes. Yet, it cannot
describe some important phenomena occurring during the journey of the
tubes across the convection zone. This review summarizes five of those
processes. One of them is related to the dramatic off-axis expansion
suffered by the top of some magnetic tubes of moderate field strength in
the middle of the convection zone (a phenomenon dubbed explosion) as a
consequence of the adiabatic character of their evolution. Another one
concerns the expansion that all rising tubes experience in the final few
$10,000$ km below the photosphere. Further, the thin flux tube
approximation does not account for the development of vorticity and
twist in the magnetic tubes (or only under very restrictive
circumstances). However, vorticity and twist are fundamental ingredients
that have to be considered at various stages of the rise. Without twist,
the buoyant tubes tend to split and yield vortex filament pairs which
separate horizontally instead of rising. The transverse field component
of a twisted tube helps maintain the unity of the tube, but it yields an
evolutionary pattern far more complicated than as described by the thin
flux tube approximation. All this is explained on the basis of the
recent results of two-dimensional MHD simulations of the initial stages
of the rise. Finally, the back reaction of the external medium to the
advance of the magnetic region is difficult to treat in the thin tube
approximation. The simple local prescription commonly used is
inconsistent in that it is based on the assumption of a potential (i.e.,
essentially non-local) flow around the tube. As a result, the expression
for the enhanced inertia it yields may violate the condition of global
momentum conservation. In the final section of the paper, the validity
of the local approach for a rectilinear and non-rotating tube as well as
its failure in more general cases are explained.