Constraining mixing in massive stars in the Small Magellanic Cloud

Context. The evolution of massive stars is strongly influenced by internal mixing processes such as semiconvection, convective core overshooting, and rotationally induced mixing. None of these processes are currently well constrained. Aims. We investigate models for massive stars in the Small Magellanic Cloud (SMC), for which stellar-wind mass loss is less important than for their metal-rich counterparts. We aim to constrain the various mixing efficiencies by comparing model results to observations. Methods. For this purpose, we use the stellar-evolution code MESA to compute more than 60 grids of detailed evolutionary models for stars with initial masses of 9…100 M⊙, assuming different combinations of mixing efficiencies of the various processes in each grid. Our models evolve through core hydrogen and helium burning, such that they can be compared with the massive main sequence and supergiant population of the SMC. Results. We find that for most of the combinations of the mixing efficiencies, models in a wide mass range spend core-helium burning either only as blue supergiants, or only as red supergiants. The latter case corresponds to models that maintain a shallow slope of the hydrogen/helium (H/He) gradient separating the core and the envelope of the models. Only a small part of the mixing parameter space leads to models that produce a significant number of blue and red supergiants, which are both in abundance in the SMC. Some of our grids also predict a cut-off in the number of red supergiants above log L/L⊙ = 5…5.5. Interestingly, these models contain steep H/He gradients, as is required to understand the hot, hydrogen-rich Wolf-Rayet stars in the SMC. We find that unless it is very fast, rotation has a limited effect on the H/He profiles in our models. Conclusions. While we use specific implementations of the considered mixing processes, they comprehensively probe the two first-order structural parameters, the core mass and the H/He gradient in the core-envelope interface. Our results imply that in massive stars, mixing during the main-sequence evolution leads to a moderate increase in the helium core masses, and also that the H/He gradients above the helium cores become very steep. Our model grids can be used to further refine the various mixing efficiencies with the help of future observational surveys of the massive stars in the SMC, and thereby help to considerably reduce the uncertainties in models of massive star evolution.

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Convective zones in the envelope of massive stars

Symposium - International Astronomical Union ◽

10.1017/s007418090021454x ◽

1994 ◽

Vol 162 ◽

pp. 67-68

Author(s):

Frank M. Alberts

Keyword(s):

Main Sequence ◽

Massive Stars ◽

Convective Zone ◽

Helium Burning ◽

The Core ◽

Negligible Amount ◽

Stellar Models

In the calculation of stellar models with the Cox–Stewart opacities no convective zones in the outer layers of massive stars appear. The new OPAL opacities (Rogers & Iglesias, 1992) show a significant bump in the opacity near temperatures of log T = 5.2. This opacity effect results in a small convective zone in the envelope of stars with mass ranging from 15 M⊙ to 150 M⊙, apart from possible convective zones caused by ionization. This was also briefly mentioned by Glatzel & Kiriakidis (1993). For stars on the main sequence this zone is small, about 1% of its radius on the zero age main sequence up to 7% at the onset of the core helium burning and contains a negligible amount of mass. For helium burning stars, however, this convective zone moves inward, keeping the same size but containing more and more mass.

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Wolf–Rayet stars in the Small Magellanic Cloud as testbed for massive star evolution

Astronomy and Astrophysics ◽

10.1051/0004-6361/201731895 ◽

2018 ◽

Vol 611 ◽

pp. A75 ◽

Cited By ~ 15

Author(s):

A. Schootemeijer ◽

N. Langer

Keyword(s):

Main Sequence ◽

Massive Stars ◽

Magellanic Cloud ◽

Compact Objects ◽

Binary Interaction ◽

Small Magellanic Cloud ◽

Low Metallicity ◽

Black Hole Binary ◽

Stellar Models ◽

Massive Star Evolution

Context. The majority of the Wolf–Rayet (WR) stars represent the stripped cores of evolved massive stars who lost most of their hydrogen envelope. Wind stripping in single stars is expected to be inefficient in producing WR stars in metal-poor environments such as the Small Magellanic Cloud (SMC). While binary interaction can also produce WR stars at low metallicity, it is puzzling that the fraction of WR binaries appears to be about 40%, independent of the metallicity.Aim. We aim to use the recently determined physical properties of the twelve known SMC WR stars to explore their possible formation channels through comparisons with stellar models.Methods. We used the MESA stellar evolution code to construct two grids of stellar models with SMC metallicity. One of these consists of models of rapidly rotating single stars, which evolve in part or completely chemically homogeneously. In a second grid, we analyzed core helium burning stellar models assuming constant hydrogen and helium gradients in their envelopes.Results. We find that chemically homogeneous evolution is not able to account for the majority of the WR stars in the SMC. However, in particular the apparently single WR star SMC AB12, and the double WR system SMC AB5 (HD 5980) appear consistent with this channel. We further find a dichotomy in the envelope hydrogen gradients required to explain the observed temperatures of the SMC WR stars. Shallow gradients are found for the WR stars with O star companions, while much steeper hydrogen gradients are required to understand the group of hot apparently single WR stars.Conclusions. The derived shallow hydrogen gradients in the WR component of the WR+O star binaries are consistent with predictions from binary models where mass transfer occurs early, in agreement with their binary properties. Since the hydrogen profiles in evolutionary models of massive stars become steeper with time after the main sequence, we conclude that most of the hot (Teff > 60 kK ) apparently single WR stars lost their envelope after a phase of strong expansion, e.g., as the result of common envelope evolution with a lower mass companion. The so far undetected companions, either main sequence stars or compact objects, are then expected to still be present. A corresponding search might identify the first immediate double black hole binary progenitor with masses as high as those detected in GW150914.

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Core Helium Burning Evolution at 15 M⊙

Publications of the Astronomical Society of Australia ◽

10.1017/s1323358000012601 ◽

1971 ◽

Vol 2 (1) ◽

pp. 23-24 ◽

Cited By ~ 3

Author(s):

J. W. Robertson

Keyword(s):

Stellar Evolution ◽

Main Sequence ◽

Helium Burning ◽

The Core ◽

Red Supergiants

The existence of red supergiants such as those in the clusters h and χ Persei has puzzled stellar evolution theoreticians for some time. Suggested explanations for them have included stars in a stage of gravitational contraction to the main sequence, or between nuclear burnings, core helium burning stars, and stars burning carbon or oxygen in the core, but it is now generally accepted that most red supergiants are core helium burning stars.

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SPITZERSAGE-SMC INFRARED PHOTOMETRY OF MASSIVE STARS IN THE SMALL MAGELLANIC CLOUD

The Astronomical Journal ◽

10.1088/0004-6256/140/2/416 ◽

2010 ◽

Vol 140 (2) ◽

pp. 416-429 ◽

Cited By ~ 106

Author(s):

A. Z. Bonanos ◽

D. J. Lennon ◽

F. Köhlinger ◽

J. Th. van Loon ◽

D. L. Massa ◽

...

Keyword(s):

Massive Stars ◽

Magellanic Cloud ◽

Small Magellanic Cloud ◽

Infrared Photometry

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The VISCACHA survey – II. Structure of star clusters in the Magellanic Clouds periphery

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/staa2425 ◽

2020 ◽

Vol 498 (1) ◽

pp. 205-222

Author(s):

João F C Santos ◽

Francisco F S Maia ◽

Bruno Dias ◽

Leandro de O Kerber ◽

Andrés E Piatti ◽

...

Keyword(s):

Surface Brightness ◽

Structural Parameters ◽

Star Clusters ◽

Large Magellanic Cloud ◽

Magellanic Cloud ◽

The Core ◽

Optical Images ◽

Low Surface Brightness ◽

Homogeneous Set ◽

Stellar Density

ABSTRACT We provide a homogeneous set of structural parameters of 83 star clusters located at the periphery of the Small Magellanic Cloud (SMC) and the Large Magellanic Cloud (LMC). The clusters’ stellar density and surface brightness profiles were built from deep, AO assisted optical images, and uniform analysis techniques. The structural parameters were obtained from King and Elson et al. model fittings. Integrated magnitudes and masses (for a subsample) are also provided. The sample contains mostly low surface brightness clusters with distances between 4.5 and 6.5 kpc and between 1 and 6.5 kpc from the LMC and SMC centres, respectively. We analysed their spatial distribution and structural properties, comparing them with those of inner clusters. Half-light and Jacobi radii were estimated, allowing an evaluation of the Roche volume tidal filling. We found that: (i) for our sample of LMC clusters, the tidal radii are, on average, larger than those of inner clusters from previous studies; (ii) the core radii dispersion tends to be greater for LMC clusters located towards the southwest, with position angles of ∼200° and about ∼5° from the LMC centre, i.e. those LMC clusters nearer to the SMC; (iii) the core radius evolution for clusters with known age is similar to that of inner clusters; (iv) SMC clusters with galactocentric distances closer than 4 kpc are overfilling; (v) the recent Clouds collision did not leave marks on the LMC clusters’ structure that our analysis could reveal.

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Massive stars burning helium: the numbers of WR stars and red supergiants in galaxies

International Astronomical Union Colloquium ◽

10.1017/s0252921100094896 ◽

1981 ◽

Vol 59 ◽

pp. 283-287

Author(s):

A. Maeder

Keyword(s):

Mass Loss ◽

Massive Stars ◽

Short Note ◽

Evolutionary Models ◽

Helium Burning ◽

Red Supergiants ◽

Low Mass ◽

Age Sequence ◽

Carbon Burning ◽

Loss Rates

We have calculated evolutionary models of massive stars in the range 15-120 Mʘ from the zero-age sequence up to the end of the carbon burning stage (Maeder, 1981). Three sets of models with different mass loss rates Ṁ have been computed; the adopted parametrisation of Ṁ is fitted on the observations and thus the expression for Ṁ differs according to the location of the stars in the HRD.In this short note we concentrate on the location of the He-burning stars in the HRD. The helium burning phase, which lasts 8 to 10% of the MS phase, is spent mainly as red supergiants (RSG) and as WR stars (note that for low mass loss, the time spent as A-G supergiants becomes longer).

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PHOTOMETRIC DETERMINATION OF THE MASS ACCRETION RATES OF PRE-MAIN-SEQUENCE STARS. II. NGC 346 IN THE SMALL MAGELLANIC CLOUD

The Astrophysical Journal ◽

10.1088/0004-637x/740/1/11 ◽

2011 ◽

Vol 740 (1) ◽

pp. 11 ◽

Cited By ~ 38

Author(s):

Guido De Marchi ◽

Nino Panagia ◽

Martino Romaniello ◽

Elena Sabbi ◽

Marco Sirianni ◽

...

Keyword(s):

Main Sequence ◽

Photometric Determination ◽

Magellanic Cloud ◽

Small Magellanic Cloud ◽

Main Sequence Stars ◽

Accretion Rates

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MUSE Observations of NGC330 in the Small Magellanic Cloud: Helium Abundance of Bright Main-sequence Stars

The Astronomical Journal ◽

10.3847/1538-3881/ab7334 ◽

2020 ◽

Vol 159 (4) ◽

pp. 152

Author(s):

R. Carini ◽

K. Biazzo ◽

E. Brocato ◽

L. Pulone ◽

L. Pasquini

Keyword(s):

Main Sequence ◽

Magellanic Cloud ◽

Helium Abundance ◽

Small Magellanic Cloud ◽

Main Sequence Stars

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Origin and Evolution of Wolf-Rayet Stars

Symposium - International Astronomical Union ◽

10.1017/s0074180900029107 ◽

1982 ◽

Vol 99 ◽

pp. 377-381

Author(s):

A. Tutukov ◽

L. Yungelson

Keyword(s):

Mass Loss ◽

Massive Stars ◽

Close Binary ◽

Initial Mass ◽

Convective Stability ◽

Helium Burning ◽

Origin And Evolution ◽

The Core

The larger part of close binary components with initial mass exceeding ∼20 Mo becomes WR stars in the core helium burning stage. Some of the most massive WR stars may be products of evolution of single massive stars with initial masses exceeding ∼50 M0 if the mass loss in the infrared supergiant stage is effective enough. The Ledoux criterion of convective stability seems more promising to explain the observed properties of WR stars.

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