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Título : New predictions for radiation-driven, steady-state mass-loss and wind-momentum from hot, massive stars II. A grid of O-type stars in the Galaxy and the Magellanic Clouds
Autor : Björklund, R.
Sundqvist, J. O.
Puls, J.
Najarro, F.
Palabras clave : Stars: atmospheres;Stars: early type;Stars: massive;Stars: mass loss;Stars: winds;Outflows;Magellanic Clouds
Fecha de publicación : 8-abr-2021
Editorial : EDP Sciences
DOI: 10.1051/0004-6361/202038384
Versión del Editor: https://www.aanda.org/articles/aa/abs/2021/04/aa38384-20/aa38384-20.html
Citación : Astronomy and Astrophysics 648: A36(2021)
Resumen : Context. Reliable predictions of mass-loss rates are important for massive-star evolution computations. Aims. We aim to provide predictions for mass-loss rates and wind-momentum rates of O-type stars, while carefully studying the behaviour of these winds as functions of stellar parameters, such as luminosity and metallicity. Methods. We used newly developed steady-state models of radiation-driven winds to compute the global properties of a grid of O-stars. The self-consistent models were calculated by means of an iterative solution to the equation of motion using full non-local thermodynamic equilibrium radiative transfer in the co-moving frame to compute the radiative acceleration. In order to study winds in different galactic environments, the grid covers main-sequence stars, giants, and supergiants in the Galaxy and both Magellanic Clouds. Results. We find a strong dependence of mass-loss on both luminosity and metallicity. Mean values across the grid are Ṁ~L*2.2 and Ṁ~L*0.95; however, we also find a somewhat stronger dependence on metallicity for lower luminosities. Similarly, the mass loss-luminosity relation is somewhat steeper for the Small Magellanic Cloud (SMC) than for the Galaxy. In addition, the computed rates are systematically lower (by a factor 2 and more) than those commonly used in stellar-evolution calculations. Overall, our results are in good agreement with observations in the Galaxy that properly account for wind-clumping, with empirical Ṁ versus Z* scaling relations and with observations of O-dwarfs in the SMC. Conclusions. Our results provide simple fit relations for mass-loss rates and wind momenta of massive O-stars stars as functions of luminosity and metallicity, which are valid in the range Teff = 28 000–45 000 K. Due to the systematically lower values for Ṁ, our new models suggest that new rates might be needed in evolution simulations of massive stars.
Descripción : Accepted for publication in A&A. 16 pages, 13
URI : http://hdl.handle.net/20.500.12666/492
E-ISSN : 1432-0746
ISSN : 0004-6361
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