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Main Sequence Abundances, Mass Loss and Meridional Circulation

Published online by Cambridge University Press:  12 April 2016

Georges Michaud*
Affiliation:
Département de Physique, Université de Montréal Montréal, Québec, CANADA H3C 3J7

Abstract

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Constraints that abundance anomalies observed on main sequence stars put on turbulence, meridional circulation and mass loss are reviewed. The emphasis is on recent observations of Li abundances.

Upper limits to turbulence are obtained from the Be abundance in the Sun and from underabundances of Ca and Sc in FmAm stars. The Li abundance in G type stars suggests the presence of turbulence below convection zones.

The abundance anomalies, both over and underabundances, observed in FmAm and λ Booti stars can be explained by diffusion in the presence of mass loss. A mass loss rate of 10−15 Mo yr−1 is required to explain the FmAm stars while a mass loss rate of 10−13 Mo yr−1 is required by the λ Booti stars.

The position and width of the Li abundance gap observed in Hyades and other open clusters is explained by diffusion. A detailed reproduction of the Li(Teff) curve seems to require a mass loss rate of slightly more than 10−15 Mo yr−1, of the same order as the mass loss rate required by the FmAm stars. In the presence of such a mass loss only small overabundances of heavy elements are expected. The observed variations in the Li abundance as a function of the age of clusters suggests that the Li abundance observed in old halo stars does not represent the cosmological abundance.

Detailed two dimensional calculations of diffusion in presence of meridional circulation for HgMn and FmAm stars lead to a cut-off of about 100 km s−1 for the maximum equatorial rotational velocity at which abundance anomalies are expected in these objects. This agrees with observations. A similar calculation for the F stars of the Hyades where Li underabundances are observed leads to a contradiction, unless meridional circulation patterns are modified by the presence of convection zones once they become as large as in late F stars. There remains a possibility that meridional circulation would be responsible for some of the reduction of the Li abundance as observed in the Hyades and UMa. Further observations are suggested to distinguish the effects of settling and nuclear destruction.

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

References

Abt, H.A., and Levy, S.G. 1985, Ap. J. Suppl., 59, 229.Google Scholar
Baglin, A., Morel, P., and Schatzman, E. 1985, Astr. Ap., 149, 309.Google Scholar
Baschek, B., and Searle, L. 1969, Ap. J., 155, 537.Google Scholar
Boeseaard, A.M. 1976, Ap. J., 210, 466.Google Scholar
Boesgaard, A.M. 1987, Pub. A. S. P., in press.Google Scholar
Boesgaard, A.M., Budge, K.G., and Burek, E.E. 1988, Ap. J., February.Google Scholar
Boesgaard, A.M., and Lavery, R.J. 1986, Ap. J., 309, 762.Google Scholar
Boesgaard, A.M., and Tripicco, M.J. 1986a, Ap. J. (Letters), 302, L49.Google Scholar
Boesgaard, A.M., and Tripicco, M.J. 1986b, Ap. J., 303, 724.Google Scholar
Boesgaard, A.M., and Tripicco, M.J. 1987, preprint.Google Scholar
Burkhart, C., Coupry, M.P., Lunel, M., and Van’t Veer, C. 1987, Astr. Ap., in press.Google Scholar
Cayrel, R., Cayrel de Strobel, G., Campbell, B., and Dappen, W. 1984, Ap. J., 283, 205.Google Scholar
Charbonneau, P., and Michaud, G. 1987a, submitted for publication.Google Scholar
Charbonneau, P., and Michaud, G. 1987b, in preparation.Google Scholar
Duncan, D.K. 1981, Ap. J., 248, 651.Google Scholar
Duncan, D.K., and Jones, B.F. 1983, Ap. J., 271, 663.Google Scholar
Guzik, J.A., Willson, L.A., and Brunish, W.M. 1987, Ap. J., 319, 957.Google Scholar
Hobbs, L.M. 1984, Ap. J., 286, 252.Google Scholar
Hobbs, L.M., and Duncan, D.K. 1987, Ap. J., 317, 796.CrossRefGoogle Scholar
Hobbs, L.M., and Pilachowski, C. 1986a, Ap. J. (Letters), 309, L17.Google Scholar
Hobbs, L.M., and Pilachowski, C. 1986b, Ap. J. (Letters), 311, L37.Google Scholar
Michaud, G. 1977, Nature, 266, 433.Google Scholar
Michaud, G. 1982, Ap. J., 258, 349.Google Scholar
Michaud, G. 1985, in Solar Neutrinos and Neutrino Astronomy, Ed. Cherry, M.L, Lande, K. and Fowler, W.A. (New York: American Institute of Physics),p. 75.Google Scholar
Michaud, G., 1986, Ap. J., 302, 650.Google Scholar
Michaud, G., Charland, Y. 1986, Ap. J., 311, 326.CrossRefGoogle Scholar
Michaud, G., Charland, Y., Vauclair, S., and Vauclair, G. 1976, Ap. J.,210, 447.Google Scholar
Michaud, G., Fontaine, G., and Beaudet, G. 1984, Ap. J.,282, 206 Google Scholar
Michaud, G., Tarasick, D., Charland, Y., and Pelletier, C., 1983, Ap. J., 269, 239.Google Scholar
Paquette, C., Pelletier, C., Fontaine, G., and Michaud, G. 1986, Ap. J. Suppl., 61, 177 Google Scholar
Pilachowski, C.A., and Hobbs, L.M. 1987, preprint.Google Scholar
Schatzman, E. 1969, Astr. Ap., 3, 331 Google Scholar
Schatzman, E. 1977, Astr. Ap., 56, 211.Google Scholar
Schatzman, E., Maeder, A., Angrand, F., and Glowinski, R. 1981, Astr. Ap., 96, 1 Google Scholar
Spite, F., and Spite, M. 1982, Astr. Ap. 115, 357 Google Scholar
Spite, M., Maillard, J.-P., and Spite, F. 1984, Astr. Ap., 141, 56.Google Scholar
Tassoul, J.-L., and Tassoul, M. 1982, Ap. J. Suppl., 49, 317 Google Scholar
Tassoul, M., and Tassoul, J.-L. 1983, Ap. J., 271, 315 CrossRefGoogle Scholar
Tassoul, M., and Tassoul, J.-L. 1984, Ap. J., 279, 384 Google Scholar
Thévenin, F., Vauclair, S., and Vauclair, G. 1986, Astr. Ap., 166, 216 Google Scholar
Tomkin, J., Lambert, D.L., and Balachandran, S. 1985, Ap. J. 290, 289.Google Scholar
Van’t Veer-Menneret, C., Coupry, M.F., and Burkhart, C. 1985, Astr. Ap., 146, 139 Google Scholar
Vauclair, G., Vauclair, S., and Michaud, G. 1978a, Ap. J., 223, 920 Google Scholar
Vauclair, S., Vauclair, G., Schatzman, E., and Michaud, G. 1978b, Ap. J., 223, 567 Google Scholar
Wolff, S.C., and Preston, G.W. 1978, Ap. J. (Suppl.). 37, 371.Google Scholar