The IACOB project

Britavskiy, N.; Holgado, G.; Burssens, S.; Apellániz, J. Maíz; Eldridge, J. J.; Nazé, Yaël; González, M. Pantaleoni; Herrero, A.

doi:10.1051/0004-6361/202245145

Cited by 9 publications

(9 citation statements)

References 137 publications

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“…The position of primaries of the selected systems on the Hertzsprung-Russell (HR) diagram is presented in Fig. 1 together with a sample of 50 Galactic fast-rotating O stars from Britavskiy et al (2023) for reference. In addition, we calculated the evolutionary tracks that represent the main-sequence evolutionary stage of a nonrotating single star at solar metallicity (Z = 0.02).…”

Section: Sample Of Stars and The Adopted Methodologymentioning

confidence: 99%

“…stellar lifetimes (i.e., HD 165246). Interestingly, according to Mahy et al (2022), more long-period and highly eccentric binaries among the initial sample of SB1 fast rotators from Britavskiy et al (2023) could possibly host a neutron star. However, according to their spectroscopic disentangling simulations, only the secondaries with M 2 3 M can be detected in the available spectra.…”

Section: Observational Contextmentioning

confidence: 99%

“…Such binary interactions may also play a dominant role in shaping the observed distribution of the surface rotation rate, especially for the tail of fast rotators because of tides, mass transfer, or mergers. This idea has been proposed multiple times, both from a theoretical perspective (Packet 1981;Pols & Marinus 1994;de Mink et al 2013;Vinciguerra et al 2020) and observational studies (Blaauw 1993;Ramírez-Agudelo et al 2015;Cazorla et al 2017;Britavskiy et al 2023). One example is the famous category of Be stars, which are fast-rotating stars with decretion disks (Frémat et al 2005;Rivinius et al 2013).…”

Section: Introductionmentioning

confidence: 99%

“…Here, we study known Galactic fast-rotating OB stars that have been identified in single-lined spectroscopic binaries, specifically HD 25631, HD 191495, and HD 46485 (SB1;Britavskiy et al 2023;Nazé et al 2023, see also Table 1). Taking into account their high surface rotational velocities (v sin i > 200 km s −1 ), short orbital periods (P < 7 days), and very unequal mass ratios, we aim to understand what causes such a high rotation, and to determine what the effect is (if any) of past and future binary interactions.…”

Section: Introductionmentioning

confidence: 99%

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Tracing the evolution of short-period binaries with super-synchronous fast rotators

Britavskiy,

Renzo,

Nazé

et al. 2024

A&A

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The initial distribution of rotational velocities of stars is still poorly known, and how the stellar spin evolves from birth to the various end points of stellar evolution is an actively debated topic. Binary interactions are often invoked to explain the existence of extremely fast-rotating stars ( The primary mechanisms through which binaries can spin up stars are tidal interactions, mass transfer and possibly mergers. However, fast rotation could also be primordial, that is, a result of the star formation process. To evaluate these scenarios, we investigated in detail the evolution of three known fast-rotating stars in short-period spectroscopic and eclipsing binaries, namely HD\,25631, HD\,191495, and HD\,46485 with primaries of masses of 7, 15, and 24 odot $, respectively, with companions of $ and orbital periods of less than 7 days. These systems belong to a recently identified class of binaries with extreme mass ratios, whose evolutionary origin is still poorly understood. We evaluated in detail three scenarios that could explain the fast rotation observed in these binaries: it could be primordial, a product of mass transfer, or the result of a merger within an originally triple system. We also discuss the future evolution of these systems to shed light on the impact of fast rotation on binary products. We computed grids of single and binary MESA models varying tidal forces and initial binary architectures to investigate the evolution and reproduce observational properties of these systems. When considering the triple scenario, we determined the region of parameter space compatible with the observed binaries and used a publicly available machine-learning model to determine the dynamical stability of the triple system. We find that, because of the extreme mass-ratio between binary components, tides have a limited impact, regardless of the prescription used, and that the observed short orbital periods are at odds with post-mass-transfer scenarios. We also find that the overwhelming majority of triple systems compatible with the observed binaries are dynamically unstable and would be disrupted within years of formation, forcing a hypothetical merger to happen so close to a zero-age main-sequence that it could be considered part of the star formation process. The most likely scenario to form such young, rapidly rotating, and short-period binaries is primordial rotation, implying that the observed binaries are pre-interaction ones. Our simulations further indicate that such systems will subsequently go through a common envelope and likely merge. These binaries show that the initial spin distribution of massive stars can have a wide range of rotational velocities.

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Section: Sample Of Stars and The Adopted Methodologymentioning

confidence: 99%

Section: Observational Contextmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Tracing the evolution of short-period binaries with super-synchronous fast rotators

Britavskiy,

Renzo,

Nazé

et al. 2024

A&A

Self Cite

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“…The initial rotation rate could in addition further increase during main sequence evolution (Ekström et al 2008). An alternative scenario, with some empirical support (Holgado et al 2022;Britavskiy et al 2023), relies on interactions within a binary system (Podsiadlowski et al 1992;van Bever & Vanbeveren 1997;de Mink et al 2013). There are several ways in which the rotation of a star may be affected by its companion.…”

Section: Introductionmentioning

confidence: 99%

Extreme mass ratios and fast rotation in three massive binaries

Nazé,

Britavskiy,

Rauw

et al. 2023

Monthly Notices of the Royal Astronomical Society

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The origin of rapid rotation in massive stars remains debated, although binary interactions are now often advocated as a cause. However, the broad and shallow lines in the spectra of fast rotators make direct detection of binarity difficult. In this paper, we report on the discovery and analysis of multiplicity for three fast-rotating massive stars: HD 25631 (B3V), HD 191495 (B0V), and HD 46485 (O7V). They display strikingly similar TESS light curves, with two narrow eclipses superimposed on a sinusoidal variation due to reflection effects. We complement these photometric data by spectroscopy from various instruments (X-Shooter, Espadons, FUSE...), to further constrain the nature of these systems. The detailed analyses of these data demonstrates that the companions of the massive OB stars have low masses (∼1 M⊙) with rather large radii (2–4 R⊙) and low temperatures (<15 kK). These companions display no UV signature, which would exclude a hot subdwarf nature, but disentangling of the large set of X-Shooter spectra of HD 25631 revealed the typical signature of chromospheric activity in the companion’s spectrum. In addition, despite the short orbital periods (P = 3 − 7 d), the fast-rotating OB-stars still display non-synchronized rotation and all systems appear young (<20 Myr). This suggests that, as in a few other cases, these massive stars are paired in those systems with non-degenerate, low-mass PMS companions, implying that fast rotation would not be a consequence of a past binary interactions in their case.

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Galactic runaway O and Be stars found usingGaiaDR3

Carretero-Castrillo,

Ribó,

Paredes

2023

A&A

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Context. A relevant fraction of massive stars are runaway stars. These stars move with a significant peculiar velocity with respect to their environment. Aims. We aim to discover and characterize the population of massive and early-type runaway stars in the GOSC and BeSS catalogs using Gaia DR3 astrometric data. Methods. We present a two-dimensional method in the velocity space to discover runaway stars as those that deviate significantly from the velocity distribution of field stars. Field stars are considered to follow the Galactic rotation curve. Results. We found 106 O runaway stars, 42 of which were not previously identified as runaways. We found 69 Be runaway stars, 47 of which were not previously identified as runaways. The dispersion of runaway stars is a few times higher in Z and b than that of field stars. This is explained by the ejections they underwent when they became runaways. The percentage of runaways is 25.4% for O-type stars, and it is 5.2% for Be-type stars. In addition, we conducted simulations in three dimensions for our catalogs. They revealed that these percentages could increase to ∼30% and ∼6.7%, respectively. Our runaway stars include seven X-ray binaries and one gamma-ray binary. Moreover, we obtain velocity dispersions of ∼5 km s−1 perpendicular to the Galactic plane for O- and Be-type field stars. These values increase in the Galactic plane to ∼7 km s−1 for O-type stars due to uncertainties and to ∼9 km s−1 for Be-type stars due to Galactic velocity diffusion. Conclusions. The excellent Gaia DR3 astrometric data have allowed us to identify a significant number of O-type and Be-type runaways in the GOSC and BeSS catalogs. The higher percentages and higher velocities found for O-type compared to Be-type runaways underline that the dynamical ejection scenario is more likely than the binary supernova scenario. Our results open the door to identifying new high-energy systems among our runaways by conducting detailed studies.

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The IACOB project

Cited by 9 publications

References 137 publications

Tracing the evolution of short-period binaries with super-synchronous fast rotators

Tracing the evolution of short-period binaries with super-synchronous fast rotators

Extreme mass ratios and fast rotation in three massive binaries

Galactic runaway O and Be stars found usingGaiaDR3

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