In this chapter, we review the modelling and pre-supernova evolution of massive stars with a particular emphasis on the effects of rotation and mass loss. We then present the stellar wind contribution to nucleosynthesis and the production of weak s process at various metallicities (Z). We also review the transition between intermediate-mass and massive stars and the major nuclear and stellar uncertainties involved. Rotation and mass loss both have a strong impact on the evolution and nucleosynthesis in massive stars. The effects of rotation on pre-supernova models are most spectacular for stars between 15 and 25 M ˇ. For M > 30Mˇ,30Mˇ30Mˇ, mass loss dominates over the effects of rotation. Massive stars near solar metallicity lose more than half their initial mass for stars more massive than 20 M ˇ. The stellar wind contribution to nucleosynthesis consists mostly of hydrogen-burning products and to a smaller extent helium-burning products since mass loss is generally small during the advanced phases. At low and very low Z, one expects mass loss and the production of secondary elements like 14 N to decrease and gradually become negligible. Rotation changes this picture. For the most massive stars (M & 60 M ˇ), primary production of CNO elements raises the overall metallicity of the surface drastically, and significant mass loss may occur during the red supergiant stage. The production R
CITATION STYLE
Hirschi, R. (2017). Pre-supernova Evolution and Nucleosynthesis in Massive Stars and Their Stellar Wind Contribution. In Handbook of Supernovae (pp. 1879–1929). Springer International Publishing. https://doi.org/10.1007/978-3-319-21846-5_82
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