Bibcode
Moreno-Insertis, F.
Bibliographical reference
4th Hinode Science Meeting: Unsolved Problems and Recent Insights, ASP Conference series, Vol 455, proceedings of a conference held 11-15 October 2010 in Palermo, Italy. Edited by Luis R. Bellot Rubio, Fabio Reale, and Mats Carlsson. San Francisco: Astronomical Society of the Pacific, 2012, p.91
Advertised on:
5
2012
Citations
2
Refereed citations
2
Description
Recent advances in the observation and numerical modeling of magnetic
flux emergence on small-scales are reviewed. The high-resolution limit
of solar photospheric observations has reached scales of order 0".2, or
100-200 km, in recent years. Observations with that resolution
show individual flux tubes emerging within single granules in the quiet
Sun as small bipolar features of flux as low as 1016 Mx.
Also, high-resolution observations of emerging ephemeral active regions
have been carried out simultaneously at heights from the photosphere to
the corona using different instruments in space and on the ground, and
providing views of the emergence process with unprecedented detail.
This paper starts with a brief review of some of the highest-resolution
flux emergence observations. On the theory side, there is an increasing
number of realistic numerical simulations of flux emergence that solve
the equations of magnetohydrodynamics and radiation transfer. Various
groups have studied different aspects of the radiation-MHD modeling of
flux emergence, but their simulations in part cover the same processes.
In this paper, a number of conclusions of the models are discussed with
special focus on the comparison between the results of the different
groups. The removal of magnetic fields from the surface is a less
explored field than the inverse process, both observationally and
theoretically. Yet, there is a good number of observations of flux
disappearance from the photosphere and other atmospheric layers,
typically in the form of cancellation of colliding flux elements of
opposite polarity. On the simulation side, various numerical experiments
of emerging flux regions find clear instances of flux cancellation and
removal in the runs. In those cases, reconnection of field lines of
opposite polarity is taking place and leads to phenomena akin to those
reported in some of the observations. In this review a number of recent
results from theory and observation are discussed which help understand
the removal of flux from the solar atmosphere.