About: Shock-heated radiation-driven outflows as a solution to the weak-wind problem of late O-type stars

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Attributs	Valeurs
type	work Article
Is Part Of	http://hub.abes.fr/edp/periodical/aa/2021/volume_648/issue_2021/w
Subject	Stellar atmospheres radiation: dynamics stars: mass-loss instabilities line: profiles stars: winds, outflows
Title	Shock-heated radiation-driven outflows as a solution to the weak-wind problem of late O-type stars
Date	2021-01-01(xsd:dateTime)
has manifestation of work	http://hub.abes.fr/edp/periodical/aa/2021/volume_648/issue_2021/aa39972-20/m/print http://hub.abes.fr/edp/periodical/aa/2021/volume_648/issue_2021/aa39972-20/m/web
related by	http://hub.abes.fr/edp/periodical/aa/2021/volume_648/issue_2021/aa39972-20/authorship/1 http://hub.abes.fr/edp/periodical/aa/2021/volume_648/issue_2021/aa39972-20/authorship/2 http://hub.abes.fr/edp/periodical/aa/2021/volume_648/issue_2021/aa39972-20/authorship/3 http://hub.abes.fr/edp/periodical/aa/2021/volume_648/issue_2021/aa39972-20/authorship/4 http://hub.abes.fr/edp/periodical/aa/2021/volume_648/issue_2021/aa39972-20/authorship/5
Author	Lagae, C. Lagae, C. Sundqvist, J. O. Driessen, F. A. Hennicker, L. Kee, N. D. Kee, N. D. Driessen, F. A. Sundqvist, J. O.
Abstract	Context. Radiation-driven mass loss is key to our understanding of massive-star evolution. However, for low-luminosity O-type stars there are big discrepancies between theoretically predicted and empirically derived mass-loss rates (called the weak-wind problem). Aims. We compute radiation-line-driven wind models of a typical weak-wind star to determine its temperature structure and the corresponding impact on ultra-violet (UV) line formation. Methods. We carried out hydrodynamic simulations of the line-deshadowing instability (LDI) for a weak-wind star in the Galaxy. Subsequently, we used this LDI model as input in a short-characteristics radiative transfer code to compute synthetic UV line profiles. Results. We find that the line-driven weak wind is significantly shock heated to high temperatures and is unable to cool down efficiently. This results in a complex temperature structure where more than half of the wind volume has temperatures significantly higher than the stellar effective temperature. Therefore, a substantial portion of the weak wind will be more ionised, resulting in a reduction of the UV line opacity and therefore in weaker line profiles for a given mass-loss rate. Quantifying this, we find that weak-wind mass-loss rates derived from unsaturated UV lines could be underestimated by a factor of between 10 and 100 if the high-temperature gas is not properly taken into account in the spectroscopic analysis. This offers a tentative basic explanation for the weak-wind problem: line-driven weak winds are not really weaker than theoretically expected, but rather a large portion of their wind volume is much hotter than the stellar effective temperature.
article type	research-article
publisher identifier	aa39972-20
Date Copyrighted	2021-01-01(xsd:dateTime)
Rights	© ESO 2021
Rights Holder	ESO
is part of this journal	Astronomy & Astrophysics
is primary topic of	http://hub.abes.fr/edp/periodical/aa/2021/volume_648/issue_2021/aa39972-20/w/record

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