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Astron. Astrophys. 336, 667-681 (1998)
The planetary nebulae populations in five galaxies:
abundance patterns and evolution
*
G. Stasi
ska 1,
M.G. Richer 2 and
M.L. Mc Call 3
1 DAEC, Observatoire de Paris-Meudon, F-92195 Meudon Cedex,
France (grazyna@obspm.fr)
2 Instituto de Astronomía, Universidad Nacional
Autónoma de México, Apdo. Postal 70 264, México
D.F. 04510, México (richer@astroscu.unam.mx)
3 Department of Physics and Astronomy, York University,
4700 Keele Street, North York, Ontario, Canada M3J 1P3
(mccall@aries.phys.yorku.ca)
Received 3 March 1998 / Accepted 19 May 1998
Abstract
We have collected photometric and spectroscopic data on planetary nebulae (PNe) in 5 galaxies: the Milky Way (bulge), M 31 (bulge), M 32, the LMC and the SMC.
We have computed the abundances of O, Ne and N and compared them
from one galaxy to another. In each Galaxy, the distribution of oxygen
abundances has a large dispersion. The average O/H ratio is larger in
the M 31 and the Galactic bulge PNe than in those in the Magellanic
Clouds. In a given galaxy, it is also larger for PNe with [O III]
luminosities greater than 100 ![[FORMULA]](img1.gif)
, which are likely
to probe more recent epochs in the galaxy history. We find that the M
31 and the Galactic bulge PNe extend the very tight Ne/H-O/H
correlation observed in the Galactic disk and Magellanic Clouds PNe
towards higher metallicities. We note that the anticorrelation between
N/O and O/H that was known to occur in the Magellanic Clouds and in
the disk PNe is also marginally found in the PNe of the Galactic
bulge. Furthermore, we find that high N/O ratios are higher for less
luminous PNe. In M 32, all PNe have a large N/O ratio, indicating that
the stellar nitrogen abundance is enhanced in this galaxy.
We have also compared the PN evolution in the different galactic systems by constructing diagrams that are independent of abundances, and have found strikingly different behaviours of the various samples.
In order to help in the interpretation of these data, we have constructed a grid of expanding, PN photoionization models in which the central stars evolve according to the evolutionary tracks of Blöcker (1995). These models show that the apparent spectroscopic properties of PNe are extremely dependent, not only on the central stars, but also on the masses and expansion velocities of the nebular envelopes.
The main conclusion of the confrontation of the observed samples with the model grids is that the PN populations are indeed not the same in the various parent galaxies. Both stars and nebulae are different. In particular, the central stars of the Magellanic Clouds PNe are shown to evolve differently from the hydrogen burning stellar evolutionary models of Blöcker (1995). In the Galactic bulge, on the other hand, the behaviour of the observed PNe is roughly compatible with the theoretical stellar evolutionary tracks. The case of M 31 is not quite clear, and additional observations are necessary. It seems that the central star mass distribution is narrower for the M 31 PNe than for the Galactic bulge PNe.
We show that spectroscopy of complete samples of PNe down to a factor 100 below the maximum luminosity would help to better characterize the PN central star mass distribution. .
Key words: ISM: planetary nebulae:
general 
stars: AGB and
post-AGB
galaxies: abundances
* Tables 1 and 2 are only available in electronic form at the CDS via anonymous
ftp to cdsarc.u-strasbg.fr (130.79.128.5) or via
http://cdsweb.u-strasbg.fr/Abstract.html
Send offprint requests to: Stasiska
Contents
- 1. Introduction
- 2. The database
- 3. PN abundance patterns in the various galaxies
- 4. An empirical comparison of the PN populations in the various galaxies
- 5. Theoretical evolution of planetary nebulae
- 6. Examination of the PN populations in the light of the model grid
- 7. Conclusion
- Acknowledgements
- References
© European Southern Observatory (ESO) 1998
Online publication: July 20, 1998
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