Bibcode
Mokiem, M. R.; de Koter, A.; Puls, J.; Herrero, A.; Najarro, F.; Villamariz, M. R.
Referencia bibliográfica
Astronomy and Astrophysics, Volume 441, Issue 2, October II 2005, pp.711-733
Fecha de publicación:
10
2005
Revista
Número de citas
133
Número de citas referidas
99
Descripción
We present the first automated fitting method for the quantitative
spectroscopy of O- and early B-type stars with stellar winds. The method
combines the non-LTE stellar atmosphere code fastwind from Puls et al.
(2005, A&A, 435, 669) with the genetic algorithm based optimization
routine pikaia from Charbonneau (1995, ApJS, 101, 309), allowing for a
homogeneous analysis of upcoming large samples of early-type stars (e.g.
Evans et al. 2005, A&A, 437, 467). In this first implementation we
use continuum normalized optical hydrogen and helium lines to determine
photospheric and wind parameters. We have assigned weights to these
lines accounting for line blends with species not taken into account,
lacking physics, and/or possible or potential problems in the model
atmosphere code. We find the method to be robust, fast, and accurate.
Using our method we analysed seven O-type stars in the young cluster Cyg
OB2 and five other Galactic stars with high rotational velocities and/or
low mass loss rates (including 10 Lac, ζ Oph, and τ Sco) that
have been studied in detail with a previous version of fastwind. The
fits are found to have a quality that is comparable or even better than
produced by the classical “by eye” method. We define
errorbars on the model parameters based on the maximum variations of
these parameters in the models that cluster around the global optimum.
Using this concept, for the investigated dataset we are able to recover
mass-loss rates down to ~6 × 10-8~M&sun;
yr-1 to within an error of a factor of two, ignoring
possible systematic errors due to uncertainties in the continuum
normalization. Comparison of our derived spectroscopic masses with those
derived from stellar evolutionary models are in very good agreement,
i.e. based on the limited sample that we have studied we do not find
indications for a mass discrepancy. For three stars we find
significantly higher surface gravities than previously reported. We
identify this to be due to differences in the weighting of Balmer line
wings between our automated method and “by eye” fitting
and/or an improved multidimensional optimization of the parameters. The
empirical modified wind momentum relation constructed on the basis of
the stars analysed here agrees to within the error bars with the
theoretical relation predicted by Vink et al. (2000, A&A, 362, 295),
including those cases for which the winds are weak (i.e. less than a few
times 10-7 M&sun; yr-1).