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Synthetic OH Band Spectra in G and K Stars

Published online by Cambridge University Press:  25 April 2016

M. S. Bessell
Affiliation:
Mount Stromio and Siding Spring Observatories, ANU.
S. M. G. Hughes
Affiliation:
Mount Stromio and Siding Spring Observatories, ANU.
P. L. Cottrell
Affiliation:
University of Canterbury N.Z.

Extract

Carbon, nitrogen and oxygen are of interest for stellar and galactic evolution for four main reasons. Firstly, they comprise most of the mass of elements heavier than helium, so their abundance reflects the bulk of chemical enrichment. Secondly, all of the oxygen, much of the carbon and perhaps some of the nitrogen is believed to be produced in shorter-lived stars more massive than those responsible for the Fe production (Tinsley 1979), so their abundance relative to Fe in very metal deficient objects should provide key information for modelling the chemical history of galaxies. Thirdly, because C and O comprise the bulk of the metals in stellar material (Fe:C:N:0 = 1:12:2.5:21 in the Sun) it is their abundance as well as that of iron, which is needed to compute evolutionary tracks for different metallicities. Finally, the O abundance will indicate whether CNO material has been mixed to the surface.

Type
Contributions
Copyright
Copyright © Astronomical Society of Australia 1984

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References

Bell, R. A., Eriksson, K., Gustafsson, B., and Nördlund, Å. Astron Astrophys Suppl., 23, 37 (1971).Google Scholar
Bessell, M. S. and Norris, J., Astrophys. J. (Lett.), 263, L29 (1982).Google Scholar
Bidelman, W. P. and MacConnell, D. J., Astron. J., 78, 687 (1973).Google Scholar
Conti, P. S., Greenstein, J. L., Spinrad, H., Wallerstein, G. and Vardya, M. S., Astrophys J., 148, 105 (1967).Google Scholar
Cottrell, P. L., PhD Thesis, ANU (1978)Google Scholar
Cottrell, P. L. and Norris, J., Astrophys J. 221, 893 (1978).Google Scholar
Goldman, A., and Gillis, J. R., J. Quant, Spectrosc. Radiat. Transfer, 25, 111 (1981).Google Scholar
Kurucz, R. L., SAO Spec. Rept., No. 309 (1970).Google Scholar
Lambert, D. L., Mon. Not. R. Astron. Soc., 182, 249 (1978).Google Scholar
Lambert, D. L., Sneden, C., and Ries, L. M., Astrophys. J., 188, (1974).Google Scholar
Moore, C. E., Minnaert, M. G. J. and Houtgast, J., NBS Monograph No. 61 (1966).Google Scholar
Norris, J., Bessell, M. S. and Pickles, A. J., in preparation (1984).Google Scholar
Sneden, C. 1973, Astrophys. J., 184, 839 (1973).Google Scholar
Tinsley, B. M., Astrophys J., 229, 1046 (1979).Google Scholar
Wehrse, R., private communication (1979).Google Scholar