Document 
-
Articles citing this article
- Same authors
-
Related articles
- Recommend this article
- Download citation
- Alert me when this article is cited
- Alert me when this article is corrected
BibSonomy
CiteUlike
Connotea
Del.icio.us
Digg
Facebook
A&A 436, 333-345 (2005)
DOI: 10.1051/0004-6361:20042553
On the fine structure of sunspot penumbrae
II. The nature of the Evershed flow
J. M. Borrero1, A. Lagg1, S. K Solanki1 and M. Collados21 Max-Planck Institut für Sonnensystemforschung, 37191 Katlenburg-Lindau, Germany
e-mail: borrero@ucar.edu, lagg@mps.mpg.de, solanki@mps.mpg.de
2 Instituto de Astrofísica de Canarias, 38200, Vía Láctea s/n, La Laguna, Tenerife, Spain
e-mail: mcv@iac.es
(Received 16 December 2004 / Accepted 4 February 2005)
Abstract
We investigate the fine structure of
the sunspot penumbra by means of a model that
allows for a flux tube in horizontal pressure balance with the
magnetic background atmosphere in which it is embedded.
We apply this model to spectropolarimetric observations
of two neutral iron lines at 1.56 
m and invert several radial
cuts in the penumbra of the same sunspot at two different heliocentric
angles. In the inner part of the penumbra we find hot flux tubes
that are somewhat inclined to the horizontal. They become gradually
more horizontal and cooler with increasing radial distance. This is
accompanied by an increase in the velocity of the plasma and a
decrease of the gas pressure difference between flux tube and
the background component. At large radial distances the flow speed
exceeds the critical speed and evidence is found for the formation
of a shock front. These results are in good agreement with
simulations of the penumbral fine structure and provide strong
support for the siphon flow as the physical mechanism driving
the Evershed flow.
Key words: Sun: sunspots -- line: profiles -- Sun: magnetic fields -- Sun: infrared
© ESO 2005
| What is OpenURL? |
