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Astron. Astrophys. 329, 551-558 (1998)
Coupled mass and angular momentum loss
of massive main sequence stars
N. Langer
Institut für Theoretische Physik und Astrophysik,
Universität Potsdam, D-14415 Potsdam, Germany
Received 28 May 1997 / Accepted 7 August 1997
Abstract
We investigate the interaction of mass loss and rotation during
core hydrogen burning in massive stars. We compute their main sequence
evolution assuming rigid rotation, and carry angular momentum as a
passive quantity in the stellar interior but incorporate its effect on
the stellar mass loss rate. We consider the example of a 60
![[FORMULA]](img1.gif)
star assuming various initial rotation
rates.
We show that rotation may substantially enhance the total main
sequence mass loss of massive stars. Furthermore, we argue that the
surface layers of rotating massive main sequence stars may reach the
limit of hydrostatic stability (" ![[FORMULA]](img2.gif)
-limit") by
achieving a considerable fraction of their Eddington luminosity. We
show that this process is not catastrophic for the star, but rather
that the coupling of mass and angular momentum loss limits the mass
loss rate ![[FORMULA]](img3.gif)
of main sequence stars at the
-limit. is determined
through the angular momentum loss imposed by the
-limit rather than by atomic physics. For our ![[FORMULA]](img4.gif)
sequences, it is ![[FORMULA]](img5.gif)
.
We find a convergence of the rotational velocities of main sequence
stars of a given initial mass at the -limit, but
a strong dependance of their mass at core hydrogen exhaustion from the
initial rotation rate. Since then also the post-main sequence
evolution depends on the initial amount of angular momentum, we argue
that this is a third independent initial parameter for the evolution
of massive stars, as important as initial mass and metallicity.
We briefly discuss observable consequences of the coupling of mass
and angular momentum loss, e.g. a significant decline of the projected
rotational velocity ![[FORMULA]](img6.gif)
towards the cool end of the
main sequence, a period of strongly enhanced and aspherical mass loss,
disks or rings in the equatorial plane of the star reminiscent of
B[e]-stars, and highly bipolar circumstellar structures.
Key words: stars:
rotation 
stars:
interiors
stars:
early-type
stars:
evolution
stars: mass loss
Contents
- 1. Introduction
- 2. Methods and assumptions
- 3. Evolutionary calculations
- 4. Discussion
- 5. Conclusions
- Acknowledgements
- References
© European Southern Observatory (ESO) 1998
Online publication: December 8, 1997
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