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Chemical Peculiarities, Mass Loss, and Final Evolution of AGB Stars in the Magellanic Clouds

Published online by Cambridge University Press:  12 April 2016

P.R. Wood*
Affiliation:
Mount Stromlo and Siding Spring Observatories Private Bag, Woden P.O., A.C.T. 2606Australia

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The Magellanic Clouds are sufficiently close that evolved stars which exhibit chemical peculiarities and the effects of mass loss can be readily observed. Such objects include carbon stars, S stars, long-period variables, OH/IR stars and planetary nebulae. Because of the relatively well-known distances of the Magellanic Clouds, the intrinsic luminosities of these objects can be accurately determined, in contrast to the situation in the Galaxy where the great majority of asymptotic giant branch (AGB) stars occur in the field population. In this review, observations of AGB stars in the Magellanic Clouds will be discussed with particular reference to those features which can shed light on mass loss and chemical peculiarities resulting from stellar evolution.

Type
Part I. Chemical Peculiarities as Probe of Stellar Evolution
Copyright
Copyright © Springer-Verlag 1988

References

Barlow, M.J. 1987, M.N.R.A.S., 227, 590.Google Scholar
Becker, S.A. and Iben, I. 1980, Ap .J., 237, 111.Google Scholar
Bessell, M.S., Wood, P.R. and Lloyd Evans, T. 1983, M.N.R.A.S., 202, 59.Google Scholar
Brett, J.M. and Bessell, M.S. 1987, Astr. Ap., submitted.Google Scholar
Dufour, R.J. 1983, in IAU Symposium 108, “Structure and Evolution of the Magellanic Clouds”, eds. van den Bergh, S. and de Boer, K.S. (Reidel), p. 353.Google Scholar
Elias, J.H., Frogel, J.A. and Schwering, P.B.W. 1986, Ap. J., 302, 675 Google Scholar
Hughes, S.M.G. and Wood, P.R. 1987, Proc. Astr. Soc. Australia, in press.Google Scholar
Iben, I. 1975, Ap.J., 196, 525 Google Scholar
Iben, I. 1977, Ap.J., 217, 788.Google Scholar
Iben, I. and Renzini, A. 1983, Ann. Rev. Astr. Ap., 21, 271 Google Scholar
Knapp, G.R. and Morris, M. 1985, Ap.J., 292, 640 Google Scholar
Lattanzio, J.C. 1986, Ap.J., 311, 708.Google Scholar
Lloyd Evans, T. 1984, M.N.R.A.S., 208, 447.Google Scholar
Meatheringham, S.J., Dopita, M.A. and Morgan, D. 1987, Ap.J., submitted.Google Scholar
Mould, J.R. and Aaronson, M. 1987, Ap.J., 303, 10 Google Scholar
Reid, N., Glass, I.S. and Catchpole, R.M. 1987, M.N.R.A.S., in press.Google Scholar
Reid, N. and Mould, J.R. 1985, Ap.J., 299, 236.Google Scholar
Renzini, A. 1980, in “Physical Processes in Red Giants”, eds. I.Iben, and Renzini, A. (Reidel), p. 431.Google Scholar
Richer, H.B., Olander, N. and Westerlund, B.E. 1979, Ap.J., 230, 724 Google Scholar
Scalo, J.M., Despain, K.M. and Ulrich, R.K. 1975, Ap.J., 196, 805 Google Scholar
Wood, P.R., Bessell, M.S. and Fox, M.W. 1983, Ap.J., 272, 99 Google Scholar
Wood, P.R., Bessell, M.S., Hughes, S.M.G., Whiteoak, J.B., Gardner, F.F. and Otrupcek, R.E. 1987a, in preparation.Google Scholar
Wood, P.R., Bessell, M.S. and Paltoglou, G. 1985, Ap.J., 290, 477 Google Scholar
Wood, P.R., Bessell, M.S. and Whiteoak, J.B. 1986, Ap.J. Letters, 306, L81.Google Scholar
Wood, P.R. and Faulkner, D.J. 1986, Ap.J., 307, 659 Google Scholar
Wood, P.R., Meatheringham, S.J., Dopita, M.A. and Morgan, D.H. 1987b, Ap. J., 320, 178.Google Scholar