The spin rates of O stars in WR+O Magellanic Cloud binaries

Shara, Michael M.; Crawford, S.; Vanbeveren, D.; Moffat, A. F. J.; Zurek, David; Crause, Lisa A.

doi:10.1093/mnras/staa038

Cited by 7 publications

(6 citation statements)

References 60 publications

(75 reference statements)

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“…Aside from projection effects, we can expect some differences between our empirical results and de Mink's simulations due to processes favoring a faster spin down than modeled, such as the formation of magnetic fields during mass accretion (as mentioned by de Mink et al 2013). Evidence supporting such processes (not necessarily a magnetic field) is found in the observation of super-synchronization but clearly subcritical rotation in OB+WR systems (Shara et al 2020). Moreover, we note that the de Mink et al ( 2013) simulation includes SB2 stars that have not been considered in our observational sample, and that the difference in metallicity -LMC for de Mink's study -could lead to a higher number of high-spin objects in their simulations.…”

Section: Exploring the Effect Of Binary Interactionsmentioning

confidence: 52%

The IACOB project

Holgado

Herrero

Barbá

2022

A&A

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Context. Stellar rotation is of key importance in the formation process, the evolution, and the final fate of massive stars. Aims. We perform a reassessment of the empirical rotational properties of Galactic massive O-type stars using the results from a detailed analysis of ground-based multi-epoch optical spectra obtained in the framework of the IACOB & OWN surveys. Methods. Using high-quality optical spectroscopy, we established the velocity distribution for a sample of 285 apparently single and single-line spectroscopic binary (SB1) Galactic O-type stars. We also made use of the rest of the parameters from the quantitative spectroscopic analysis presented in prior IACOB papers (mainly T eff , log g, and multiplicity) to study the v sin i behavior and evolution from the comparison of subsamples in different regions of the spectroscopic Hertzsprung-Rusell diagram (sHRD). Our results are compared to the main predictions -regarding current and initial rotational velocities -of two sets of well-established evolutionary models for single stars, as well as from population synthesis simulations of massive stars that include binary interaction. Results. We reassess the known bimodal nature of the v sin i distribution, and find a non-negligible difference between the v sin i distribution of single and SB1 stars. We provide empirical evidence supporting the proposed scenario that the tail of fast rotators is mainly produced by binary interactions. Stars with extreme rotation (>300 km s −1 ) appear as single stars that are located in the lower zone of the sHRD. We notice little rotational braking during the main sequence, a braking effect independent of mass (and wind strength). The rotation rates of the youngest observed stars lean to an empirical initial velocity distribution with 20% of critical velocity. Lastly, a limit in v sin i detection below 40-50 km s −1 seems to persist, especially in the upper part of the sHRD, possibly associated with the effect of microturbulence in the measurement methodology used.

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Section: Exploring the Effect Of Binary Interactionsmentioning

confidence: 52%

The IACOB project

Holgado

Herrero

Barbá

2022

A&A

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“…However, one may expect mass accretors to reach critical rotation velocities [88] of ≈ 500 − 600 km s −1 . In contrast to the theoretical expectation, post-interaction O-type mass accretors (e.g., in Wolf-Rayet binaries) are commonly observed to rotate at sub-critical velocities, with typical velocities of 200-300 km s −1 [48,89]. The reasons for this are yet to be established, but could be related to boosted mass-loss of rapid rotators or magnetic fields produced during mass-transfer [89].…”

Section: Synchronisation Circulation and Rotationmentioning

confidence: 80%

An X-ray-quiet black hole born with a negligible kick in a massive binary within the Large Magellanic Cloud

et al. 2022

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“…The observed population of Be/X-ray binaries (Reig 2011) signifies that this spin-up may achieve near-critical rotation, with strong consequences for the mass outflow from the spun-up star, and the mass accretion onto the compact companion. The Galactic and LMC WR+O binaries do indeed also contain rapidly rotating O stars (Vanbeveren et al 2018;Shara et al 2020). However, while faster than average O stars, the analysed WR companions rotate on average with less than 50% of their critical rotational velocity, implying that the centrifugal force remains below 25% of the surface gravity at the stellar equator.…”

Section: Properties Of the Wr Star Companionmentioning

confidence: 97%

X-ray emission from BH+O star binaries expected to descend from the observed galactic WR+O binaries

Sen

Langer

et al. 2021

A&A

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Context. In the Milky Way, ∼18 Wolf-Rayet+O star (WR+O) binaries are known with estimates of their stellar and orbital parameters. Whereas black hole+O star (BH+O) binaries are thought to evolve from WR+O binaries, only one such system is known in the Milky Way. To resolve this disparity, it was suggested recently that upon core collapse, the WR stars receive large kicks such that most of the binaries are disrupted. Aims. We reassess this issue, with a particular emphasis on the uncertainty in predicting the X-ray emission from wind-accreting BHs in BH+O binaries, which is key to identifying such systems. Methods. BH+O systems are thought to be X-ray bright only when an accretion disk forms around the BHs. We followed the methodology of previous work and applied an improved analytic criterion for the formation of an accretion disk around wind accreting BHs. We then used stellar evolutionary models to predict the properties of the BH+O binaries which are expected to descend from the observed WR+O binaries if the WR stars would form BHs without a natal kick. Results. We find that disk formation sensitively depends on the O stars’ wind velocity, the amount of specific angular momentum carried by the wind, the efficiency of angular momentum accretion by the BH, and the spin of the BH. We show that whereas the assumption of a low wind velocity may lead to the prediction that most of the BH+O star binaries will have an extended X-ray bright period, this is not the case when typical wind velocities of O stars are considered. We find that a high spin of the BH can boost the duration of the X-ray active phase as well as the X-ray brightness during this phase. This produces a strong bias for detecting high mass BH binaries in X-rays with high BH spin parameters. Conclusions. We find that large BH formation kicks are not required to understand the sparsity of X-ray bright BH+O stars in the Milky Way. Probing for a population of X-ray silent BH+O systems with alternative methods can likely inform us about BH kicks and the necessary conditions for high energy emission from high mass BH binaries.

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The spin rates of O stars in WR+O Magellanic Cloud binaries

Cited by 7 publications

References 60 publications

The IACOB project

The IACOB project

An X-ray-quiet black hole born with a negligible kick in a massive binary within the Large Magellanic Cloud

X-ray emission from BH+O star binaries expected to descend from the observed galactic WR+O binaries

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