Bibcode
DOI
Sobotka, Michal; Bonet, Jose A.; Vazquez, M.
Bibliographical reference
Astrophysical Journal v.415, p.832
Advertised on:
10
1993
Citations
104
Refereed citations
94
Description
A detailed study of the brightness, size, spatial distribution, and
filling factor of the different umbral inhomogeneities is presented.
Many sunspots show multiple umbrae (separated by strong light bridges,
SLBs), which behave like independent units. These are termed umbral
cores (UCs). From the phenomenological point of view, UCs show two
components: (1) a dark area, formed by a diffuse background (DB), with
local intensity minima called dark nuclei (DNs), and (2) bright features
including umbral dots (UDs) and faint light bridges (FLBs).
Slit-jaw images (bandpass 5425±50 Å) and spectra (line Fe I
5434.5 Å) of seven sunspots with 13 separate UCs were acquired
using the Swedish Solar Telescope at the Observatorio del Roque de los
Muchachos (La Palma) with a spatial resolution of 0".3. Image
restoration and inversion of the spectral line profile were applied,
with the following results:
The most important photometric parameter of the UCs is the mean
intensity of their DB (mean background intensity
‾Iback). It is well correlated to the intensity minimum
of the diffuse background and to the mean brightness of UDs. The
relation between the size of the UCs and their ‾Iback
is not straightforward, but UCs with radii <5" are in general
brighter than the larger ones. The differences in the brightness of
individual umbrae can be explained mainly by variations of
‾Iback rather than in terms of variations of UD filling
factor.
The linear relation between the peak intensity of UDs and the intensity
of the adjacent DB (local background intensity) was confirmed in a
sample of more than 1500 elements, and the "true" peak-to-background
ratio was estimated as 3.
The spatial distribution of UDs is nonuniform. In DNs (whose size is
comparable to that of photospheric granules) UDs appear very rarely;
they prefer to form clusters and alignments outside the DNs. The mean
nearest neighbor distance decreases, and the density of UDs increases
with increasing ‾Iback. The filling factor of UDs is in
the range 3%-10%, and the size of UDs is similar in all UCs. The typical
"true" size is 180-300 km, and it is uncorrelated to the peak brightness
of UDs.
FLBs are composed of bright grains and dark spaces between them. The
bright grains are darker than photospheric granules. The size of the
bright grains is similar to that of UDs, and their relative area in FLBs
is very close to the fractional area granulum-intergranulum in the quiet
photosphere.
On the basis of the obtained spectral profiles, working models of
temperature stratification are presented for UDs, their adjacent DB, and
DNs.
On the basis of observational facts the following is proposed: UDs and
FLBs are probably demonstrations of some kind of altered convection,
with a cell size of about 0".5, modulated by a smoothly varying magnetic
field.