2020
DOI: 10.1051/0004-6361/201937018
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The single star path to Be stars

Abstract: Context. Be stars are rapidly rotating B main sequence stars, which show line emission due to an outflowing disc. By studying the evolution of rotating single star models, we can assess their contribution to the observed Be star populations. Aims. We identify the main effects which are responsible for single stars to approach critical rotation as functions of initial mass and metallicity, and predict the properties of populations of rotating single stars. Methods. We perform population synthesis with single st… Show more

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Cited by 38 publications
(48 citation statements)
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“…Some aspects of Be stars remain difficult to explain with our single star models. For instance, like Hastings et al (2019), our single star models predict that Be stars are much more common near the TAMS, whereas only a mild increase is observed. Additionally, we may expect higher levels of nitrogen enrichment than observed.…”
Section: The Be Star Phenomenonmentioning
confidence: 71%
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“…Some aspects of Be stars remain difficult to explain with our single star models. For instance, like Hastings et al (2019), our single star models predict that Be stars are much more common near the TAMS, whereas only a mild increase is observed. Additionally, we may expect higher levels of nitrogen enrichment than observed.…”
Section: The Be Star Phenomenonmentioning
confidence: 71%
“…Since we now know that AM transport in radiative regions of stars is even more efficient than the TS dynamo predicts (Cantiello et al 2014), a larger fraction of Be stars should be produced. Because our AM transport prescription and the TS dynamo predict nearly rigid rotation during the MS, we expect to find similar results to Hastings et al (2019) for MS stars, though we have not performed a full population synthesis calculation. Like Hastings et al 2019, we find a 'goldilocks' range of ≈ 15-25 M (at solar metallicity) where Be star formation is most efficient, the lower bound arising from a smaller core mass and the upper bound from larger wind AM losses.…”
Section: The Be Star Phenomenonmentioning
confidence: 84%
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“…B.10. Emission features make it likely that these are late-MS stars that evolved toward critical velocity in isolation (Ekström et al 2008;Hastings et al 2020) or were aided by a binary companion (e.g., Gies et al 1998;Wang et al 2020) rather than He-burning blue supergiants. The offset of 0.05 − 0.1 dex is in line with a shift in T eff of 0.05 dex at critical rotation (Paxton et al 2019), uncertainties in overshooting (see Schootemeijer et al 2019), and modest errors.…”
Section: Blue Supergiantsmentioning
confidence: 99%