|
Документ взят из кэша поисковой машины. Адрес
оригинального документа
: http://www.stsci.edu/stsci/meetings/shst2/vallenaria.html
Дата изменения: Wed Jun 15 19:38:50 2005 Дата индексирования: Sat Dec 22 12:44:33 2007 Кодировка: Поисковые слова: http astrokuban.info astrokuban |
A. Vallenari
Osservatorio di Padova, Padova, Italy
D.J. Bomans
University of Illinois, Dept. of Astronomy, Urbana, IL 61801 USA
Sternwarte, Bonn University, Germany
S. Ortolani
Dipartimento di Astronomia, Universitá di Padova, Italy
yr
to about 4Myr ago. Older episodes
of star formation going from 1.5Gyr to 1.5 
yr ago
are evident from the data.
The process of star formation in irregular and starburst galaxies is still far from being understood, in spite of the efforts made in the recent past. While many small irregular galaxies show continuous star formation (Gallagher et al. 1984), some larger amorphous irregular galaxies are clearly bursting systems (e.g., Meurer et al. 1992, Marlowe et al. 1995).
The study of the color-magnitude diagrams is the most direct way to get
information on the star formation
for those galaxies that
are well resolved into stars. The HST with its superior spatial
resolution is a perfect tool to study nearby galaxies using this method.
NGC 1569 is a blue dwarf irregular
located at a distance of 2.2 Mpc or
(m-M)
=26.7 mag
(Israel 1988).
NGC 1569 is thought to be a prime example of a post-starburst galaxy
(Israel 1988). This galaxy has recently been studied by Heckman et al. (1995).
We obtain the CMD of NGC 1569
from HST WFPC observations (pre-refurbishment)
in the F555W and F785LP filters (hereafter
called V and I, because we fitted the magnitudes into the standard
V,I system) retrieved from the HST archive.
The two super starclusters present in this galaxy are discussed by O'Connell
et al. (1994) on the basis of two PC images of the same set we have retrieved.
No deep photometry of stars in the other PC chips has been
published by these authors.
Aperture photometry is done
using Inventory (in Midas environment) on the images
after the removal of cosmic rays and subtraction of the sky.
Two apertures (three and four pixels of diameter) are tested
and the smallest one is chosen.
Due to the particular shape of the point spread
function of HST before the refurbishment, only 15% of the light is
included in a diameter of about three pixels: even the use of such a small
aperture in the photometry allow
us to detect stars unresolved in previous ground-based studies.
The sky is measured in a sub-array of 17
17 pixels around each object.
Particular attention is paid to avoid spurious
detections in the spikes and tendrils around bright stars: we find that
a large value of the Inventory parameter Brgtctrl (
) can minimize the
problem. The reality of each star automatically found by Inventory
is checked visually on
each frame. We find 1585 stars in the whole galaxy down to I
=22.5 mag.
All the stars inside the two superclusters are discarded,
since the presence of a high concentration of bright objects
and, as a consequence, of PSF spikes and tendrils makes the
finding procedure unreliable.
Figure: CMD of NGC 1569, corrected for internal and foreground reddening,
adopting E
0.5 (Israel 1988). Isochrones
having metallicity Z=0.004 are superposed. The ages, in Gyr, are 2.5,
1.5, 1.0, 0.6, 0.4, 0.1, 0.025, 0.015, 0.01, 0.006, 0.004
To discuss the star formation in NGC 1569, we superpose
on the CMD the whole galaxy (see Fig.1) the
isochrones calculated by Fagotto et al. (1994) for Z=0.004 as
appropriate, since Dufour et al. (1982) and Hunter et al.
(1982) derive for NGC 1569 a metal content in
between those found for the LMC and the SMC.
The data presented here suggest a well-defined scenario for the
recent history of this galaxy. There is evidence of a recent burst
of star formation from about 1.5 
yr to 4Myr.
The distribution of the red stars shows that some star formation
was going on at older ages,
from 1.5Gyr to 1.5
yr. The presence of stars
at intermediate colors is related to an episode of star
formation from 1
to 1
yr.
The maximum quiescent time allowed by our data is about 5
yr.
However, longer intervals of inactivity cannot be
excluded for ages older than 1.5
yr.
The star formation of NGC 1569 was probably continuous in the past
1.5Gyr, with very brief episodes of quiescence.
Waller (1991) suggests that this galaxy has experienced about six bursts
of comparable intensity having a duration of about 2
yr.
In this scenario,
the proposed cycling time is quite uncertain, going from 2Gyr to
3
yr.
On the basis of the integrated colors of NGC 1569,
Israel (1988) predicts quiescent phases of about 6
yr.
As result of our analysis, these times seem to be too
long to account for the distribution of stars in
the CMD. This behavior is in
agreement with the results found by Marconi et al. (1995) and Tosi et al.
(1991) for other nearby Irregular galaxies where the star formation
rate in the past 1Gyr was proceeding in a gasping way.
Dufour, R.J., Shields, G.A., & Talbot, R.J. 1982, ApJ, 256, 397
Fagotto, F., Bressan, A., Bertelli, G., & Chiosi, C. 1994, A&AS, 105, 29
Heckman, T., Dahlem, M., Lehnert, M.D., Fabbiano, G., Gilmore, D., & Waller, W. 1995, ApJ, 448, 98
Gallagher, J.S., Hunter D.A., & Tutukov A.V. 1984, ApJ, 284, 544
Hunter, D.A., Gallagher, J.S., & Rautenkranz, D. 1982, ApJ, 49, 53
Israel, F.P. 1988, ApJ 194, 24
Marlowe A.T., Heckman T.M., Wyse R.F.G., & Schommer R. 1995, ApJ, 438, 563
Meurer G., Freeman K., Dopita M., & Cacciari C. 1992, AJ, 103, 60
Marconi, G., Tosi, M., Greggio, L., & Focardi, P. 1995, AJ, 109, 173
O'Connell, R.W., Gallagher, J.S., & Hunter, D.A. 1994, ApJ, 433, 65
Tosi, M., Greggio, L., Marconi, G., & Focardi, P. 1991, AJ, 102, 951
Waller, W.H. 1991, ApJ, 370, 144