Bibcode
DOI
Caligari, P.; Schuessler, M.; Moreno-Insertis, F.
Referencia bibliográfica
Astrophysical Journal v.502, p.481
Fecha de publicación:
7
1998
Número de citas
88
Número de citas referidas
72
Descripción
Numerical simulations of rising magnetic flux tubes in the solar
convection zone have contributed significantly to our understanding of
the basic properties of sunspot groups. They have provided an important
clue to the operation of the solar dynamo by predicting strong
(super-equipartition) magnetic fields near the bottom of the convection
zone. We have investigated to what extent the simulation results
(obtained on the basis of the thin flux tube approximation) depend on
the assumptions made about the initial state of a magnetic flux tube at
the start of the simulation. Two initial conditions used in the
literature have been considered in detail: mechanical equilibrium (MEQ)
and temperature balance (TBL). It turns out that the requirement of
super-equipartition field strength is a robust feature of the
simulations, largely independent of the choice of initial conditions:
emergence of active regions at low latitudes and the correct dependence
of their tilt angle (with respect to the east-west direction) as a
function of heliographic latitude require an initial magnetic field
strength on the order of 105 G. Other properties of rising flux tubes,
such as the asymmetries of shape and field strength between the leading
and following wings (with respect to the direction of rotation) of a
rising loop, or the anchoring of part of the flux tube in the overshoot
region, depend on the initial condition. Observed asymmetries in the
magnetic flux distribution and of proper motions in emerging active
regions favor MEQ over TBL as the proper initial condition. MEQ should
also be preferred for other theoretical reasons: it allows for fewer
free parameters, it requires no fine tuning for the tube geometry and
background stratification in the overshoot region, and it can be easily
made compatible with an encompassing model of the generation, storage,
and eruption of the magnetic flux. We have also studied whether an
external upflow (convective updraft) can trigger the eruption of an
otherwise stably stored flux tube in the overshoot region. We find that
a significant deformation and destabilization of a flux tube with
equipartition field strength requires coherent upflow velocities of
20-50 m s-1 in the overshoot layer, which is an order of magnitude
larger than current estimates for such velocities.