Escape from the Bermuda cluster: Orphanization by multiple stellar ejections

Apellániz, J. Maíz; González, M. Pantaleoni; Barbá, R. H.; Weiler, Michael

doi:10.1051/0004-6361/202142366

Cited by 12 publications

(12 citation statements)

References 74 publications

(63 reference statements)

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“…If SBN central stars are representative of the population of field OB stars, as is suggested by the consonance between the samples' multiplicity fractions and runaway fractions, this suggests that the DES contributes more heavily to the field OB population than BSS. The significant numbers of multiple systems ejected from young stellar clusters (Maíz Apellániz et al 2022) adds evidence to this scenario. Alternatively, given the high fraction of SBN central stars in isolated environments with low peculiar velocities ( 14 km s −1 ), this may provide evidence that a fraction of massive stars may form in relative isolation.…”

Section: Discussionmentioning

confidence: 94%

Kinematics of the Central Stars Powering Bowshock Nebulae and the Large Multiplicity Fraction of Runaway OB Stars

Kobulnicky,

Chick

2022

Preprint

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OB stars powering stellar bowshock nebulae (SBNe) have been presumed to have large peculiar velocities. We measured peculiar velocities of SBN central stars to assess their kinematics relative to the general O star population using Gaia EDR3 data for 267 SBN central stars and a sample of 455 Galactic O stars to derive projected velocities v 2D . For a subset of each sample we obtained new optical spectroscopy to measure radial velocities and identify multiple-star systems. We find a minimum multiplicity fraction of 36±6% among SBN central stars, consistent with >28% among runaway Galactic O stars. The large multiplicity fraction among runaways implicates very efficient dynamical ejection rather than binary-supernova origins. The median v 2D of SBN central stars is v 2D =14.6 km s −1 , larger than the median v 2D =11.4 km s −1 for non-bowshock O stars. Central stars of SBNe have a runaway (v 2D >25 km s −1 ) fraction of 24 +9 −7 %, consistent with the 22 +3 −3 % for controlsample O stars. Most (76%) of SBNe central stars are not runaways. Our analysis of alignment (∆ PA ) between the nebular morphological and v 2D kinematic position angles reveals two populations: a highly aligned (σ P A =25 • ) population that includes stars with the largest v 2D (31% of the sample) and a random (non-aligned) population (69%). SBNe that lie within or near H II regions comprise a larger fraction of this latter component than SBNe in isolated environments, implicating localized ISM flows as a factor shaping their orientations and morphologies. We outline a new conceptual approach to computing the Solar LSR motion, yielding [U , V , W ]= [5.5, 7.5, 4.5] km s −1 .

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Section: Discussionmentioning

confidence: 94%

Kinematics of the Central Stars Powering Bowshock Nebulae and the Large Multiplicity Fraction of Runaway OB Stars

Kobulnicky,

Chick

2022

Preprint

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“…If SBN central stars are representative of the population of field OB stars, as is suggested by the consonance between the samples' multiplicity fractions and runaway fractions, this suggests that the DES contributes more heavily to the field OB population than BSS. The significant numbers of multiple systems ejected from young stellar clusters (Maíz Apellániz et al 2022) add evidence to this scenario. Alternatively, given the high fraction of SBN central stars in isolated environments with low peculiar velocities (;14 km s −1 ), this may provide evidence that a fraction of massive stars may form in relative isolation.…”

Section: Discussionmentioning

confidence: 94%

Kinematics of the Central Stars Powering Bowshock Nebulae and the Large Multiplicity Fraction of Runaway OB Stars

Kobulnicky

Chick

2022

View full text Add to dashboard Cite

OB stars powering stellar bowshock nebulae (SBNe) have been presumed to have large peculiar velocities. We measured peculiar velocities of SBN central stars to assess their kinematics relative to the general O-star population using Gaia EDR3 data for 267 SBN central stars and a sample of 455 Galactic O stars to derive projected velocities v 2D. For a subset of each sample, we obtained new optical spectroscopy to measure radial velocities and identify multiple-star systems. We find a minimum multiplicity fraction of 36% ± 6% among SBN central stars, consistent with >28% among runaway Galactic O stars. The large multiplicity fraction among runaways implicates very efficient dynamical ejection rather than binary-supernova origins. The median v 2D of SBN central stars is v 2D = 14.6 km s−1, larger than the median v 2D = 11.4 km s−1 for non-bowshock O stars. Central stars of SBNe have a runaway (v 2D > 25 km s−1) fraction of 24 − 7 + 9 %, consistent with the 22 − 3 + 3 % for control-sample O stars. Most (76%) SBNe central stars are not runaways. Our analysis of alignment (ΔPA) between the nebular morphological and v 2D kinematic position angles reveals two populations: a highly aligned (σ PA = 25°) population that includes stars with the largest v 2D (31% of the sample) and a random (nonaligned) population (69%). SBNe that lie within or near H ii regions comprise a larger fraction of this latter component than SBNe in isolated environments, implicating localized ISM flows as a factor shaping their orientations and morphologies. We outline a new conceptual approach to computing the solar local standard of rest motion, yielding [U ⊙, V ⊙, W ⊙] = [5.5, 7.5,4.5] km s−1.

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“…Given that the periastron took place at a 3-D separation of just 18.6±1.0 AU (when the system was first spatially resolved in 1996 it was ∼375 AU), an order of magnitude (or even less) smaller than the expected semi-major axis of the inner orbit, and the high eccentricity, it is possible that the system has transitioned from an elliptic orbit to a hyperbolic trajectory and a possible ejection from Villafranca O-002 (Trumpler 14). If that had happened, this could be another example of an orphan cluster where the most (in this case, two) massive stars of a cluster are ejected through a dynamical interaction (Maíz Apellániz et al 2022b). Further observations are needed, especially with HST/STIS later in this decade (if it is still operational) when Aa and Ab are expected to reach plane-of-the-sky separations of ∼40 mas.…”

Section: Individual Starsmentioning

confidence: 99%

Gaia-ESO Survey: massive stars in the Carina Nebula. A new census of OB stars

Berlanas¹,

Apellániz²,

Herrero³

et al. 2023

Preprint

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Context. The Carina Nebula is one of the major massive star-forming regions in the Galaxy. Its relatively nearby distance (2.35 kpc) makes it an ideal laboratory for the study of massive star formation, structure and evolution, both for individual stars and stellar systems. Thanks to the high-quality spectra provided by Gaia-ESO survey and the LiLiMaRlin library, as well as Gaia EDR3 astrometry, a detailed and homogeneous spectroscopic characterization of its massive stellar content can be carried out. Aims. Our main objective is to spectroscopically characterize all massive members of the Carina Nebula in the Gaia-ESO survey footprint to provide an updated census of massive stars in the region and an updated estimate of the binary fraction of O stars. Methods. We perform accurate spectral classification by using an interactive code that compares spectra with spectral libraries of OB standards, as well as line-based classic methods. Membership is calculated using our own algorithm based on Gaia EDR3 astrometry.To check the correlation between the spectroscopic n-qualifier and the rotational velocity, we use the semi-automated tool for the line-broadening characterization of OB stars which is based on a combined Fourier Transform and Goodness-of-fit methodology. Results. The Gaia-ESO survey sample of massive OB stars in the Carina Nebula consists of 234 stars. The addition of brighter sources from the Galactic O-Star Spectroscopic Survey and additional sources from the literature allows us to create the most complete census of massive OB stars done so far in the region. It contains a total of 316 stars, being 18 of them in the background and four in the foreground. Of the 294 stellar systems in Car OB1, 74 are of O type, 214 are of non-supergiant B type and 6 are of WR or non-O supergiant (II to Ia) spectral class. We identify 20 spectroscopic binary systems with an O-star primary, of which 6 are reported for the first time, and another 18 with a B-star primary, of which 13 are new detections. The average observed double-lined binary fraction of O-type stars in the surveyed region is 0.35, which represents a lower limit. We find a good correlation between the spectroscopic n-qualifier and the projected rotational velocity of the stars. The fraction of candidate runaways among the stars with and without the n-qualifier is 4.4% and 2.4%, respectively, although non resolved double-lined binaries can be contaminating the fast rotator sample.

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Escape from the Bermuda cluster: Orphanization by multiple stellar ejections

Cited by 12 publications

References 74 publications

Kinematics of the Central Stars Powering Bowshock Nebulae and the Large Multiplicity Fraction of Runaway OB Stars

Kinematics of the Central Stars Powering Bowshock Nebulae and the Large Multiplicity Fraction of Runaway OB Stars

Kinematics of the Central Stars Powering Bowshock Nebulae and the Large Multiplicity Fraction of Runaway OB Stars

Gaia-ESO Survey: massive stars in the Carina Nebula. A new census of OB stars

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