An updated stellar census of the Quintuplet cluster

Clark, J. S.; Lohr, M. E.; Patrick, L. R.; Najarro, F.; Dong, Hui; Figer, Donald F.

doi:10.1051/0004-6361/201833041

Cited by 37 publications

(106 citation statements)

References 122 publications

(222 reference statements)

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“…Notably, the lack of H-free WRs, BHGs, and LBVs strongly argues against ages much larger than this. Comparison to the Quintuplet also suggest an upper limit to the age of the Arches of 3.6 Myr (Clark et al 2018), consistent with the above results. Unfortunately these estimates still bracket the ages at which one might expect the first SNe to occur for very massive stars (≥120 M ).…”

Section: Discussionsupporting

confidence: 87%

“…Liermann et al 2009). Of these, the faintest, potentially single stars have m F205W ∼ 11.3−11.7 mag, while those found in binaries are signficantly brighter still, ranging up to m F205W ∼ 7.2 mag (due to the formation of hot dust in the wind collision zone; Clark et al 2018). In comparison we have spectral classifications for all stars to a limit of m F205W ∼ 12.41 mag (F31, Table A.1), strongly suggesting that no WC stars are present within the Arches at this time unless subject to particularly extreme differential reddening.…”

Section: The Absence Of H-free Wrs Lbvs and Interacting Binariesmentioning

confidence: 99%

“…Trivially, the lack of cool super/hypergiants suggests an age of <5 Myr (Clark et al 2005). Fortuitously, despite suffering from a similarly uncertain extinction, a more stringent constraint is provided by the Quintuplet cluster, which hosts a substantial ∼O7-B0 supergiant population -while lacking the O4-6 supergiants found in the Arches -as well as a wealth of early B hypergiants and LBVs (Figer et al 1999b;Liermann et al 2009;Clark et al 2018). These populations are absent from the Arches, suggesting that it is a younger system.…”

Section: Comparison To Other Clustersmentioning

confidence: 99%

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The Arches cluster revisited

Clark

Lohr

Najarro

et al. 2018

A&A

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Context. Located within the central region of the Galaxy, the Arches cluster appears to be one of the youngest, densest, and most massive stellar aggregates within the Milky Way. As such, it has the potential to be uniquely instructive laboratory for the study of star formation in extreme environments and the physics of very massive stars. Aims. To realise this possibility, the fundamental physical properties of both cluster and constituent stars need to be robustly determined; tasks we attempt here. Methods. In order to accomplish these goals we provide and analyse new multi-epoch near-IR spectroscopic data obtained with the VLT/SINFONI and photometry from the HST/WFC3. We are able to stack multiple epochs of spectroscopy for individual stars in order to obtain the deepest view of the cluster members ever obtained. Results. We present spectral classifications for 88 cluster members, all of which are WNLh or O stars: a factor of three increase over previous studies. We find no further examples of Wolf–Rayet stars within the cluster; importantly no H-free examples were identified. The smooth and continuous progression in spectral morphologies from O super/hypergiants through to the WNLh cohort implies a direct evolutionary connection. We identify candidate giant and main sequence O stars spectroscopically for the first time. No products of binary evolution may be unambiguously identified despite the presence of massive binaries within the Arches. Conclusions. Notwithstanding difficulties imposed by the highly uncertain (differential) reddening to the Arches, we infer a main sequence/luminosity class V turn-off mass of ~30−38 M⊙ via the distribution of spectral types. Analysis of the eclipsing binary F2 suggests current masses of ~80 M⊙ and ~60 M⊙ for the WNLh and O hypergiant cohorts, respectively; we conclude that all classified stars have masses >20 M⊙. An age of ~2.0−3.3 Myr is suggested by the turn-off between ~O4-5 V; constraints imposed by the supergiant population and the lack of H-free WRs are consistent with this estimate. While the absence of highly evolved WC stars strongly argues against the prior occurrence of SNe within the Arches, the derived age does accommodate such events for exceptionally massive stars. Further progress will require quantitative analysis of multiple individual cluster members in addition to further spectroscopic observations to better constrain the binary and main sequence populations; nevertheless it is abundantly clear that the Arches offers an unprecedented insight into the formation, evolution and death of the most massive stars nature allows to form.

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Section: Discussionsupporting

confidence: 87%

Section: The Absence Of H-free Wrs Lbvs and Interacting Binariesmentioning

confidence: 99%

Section: Comparison To Other Clustersmentioning

confidence: 99%

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The Arches cluster revisited

Clark

Lohr

Najarro

et al. 2018

A&A

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“…BHG, LBV, sgB[e], YHG, and RSG). Surprisingly, only one LBV is identified (Wd1-243; Clark & Negueruela 2004), compared to large numbers of confirmed and candidate systems within, for example, the Quintuplet (Clark et al 2018b) 12 . Intriguingly, Wd1-243 also has a rather moderate mass-loss rate (Ritchie et al 2009b;Fenech et al 2018) in comparison to other (candidate) LBVs such as P Cygni (Najarro 2001), AG Car (Groh et al 2009) and HDE 316285 where, unlike Wd1-243, the wind densities are sufficient to drive the Paschen series into emission.…”

Section: Stellar Contentmentioning

confidence: 95%

“…No such simple scheme can be constructed for Wd1 due to an absence of transitional WN/WC stars and the range of WN spectral sub-types observed. Similarly the almost complete lack of H-free WN stars within the Quintuplet complicates interpretation of evolution from the BHG/LBV/WN9-11h to WC phase at very high initial masses ( 60 M ; Clark et al 2018b); we return to these observational findings in Sect. 4.4.…”

Section: Comparison To Other Young Massive Clustersmentioning

confidence: 98%

A VLT/FLAMES survey for massive binaries in Westerlund 1

Clark

Ritchie

Negueruela

2020

A&A

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Context. The formation, properties, and evolution of massive stars remain subject to considerable theoretical and observational uncertainty. This impacts on fields as diverse as galactic feedback, the production of cosmic rays, and the nature of the progenitors of both electromagnetic and gravitational wave transients. Aims. The young massive clusters many such stars reside within provide a unique laboratory for addressing these issues. In this work we provide a comprehensive stellar census of Westerlund 1 in order to to underpin such efforts. Methods. We employed optical spectroscopy of a large sample of early-type stars to determine cluster membership for photometrically-identified candidates, characterise their spectral type, and identify new candidate spectroscopic binaries. Results. Sixty nine new members of Westerlund 1 are identified via I-band spectroscopy. Together with previous observations, they illustrate a smooth and continuous morphological sequence from late-O giant through to OB supergiant. Subsequently, the progression bifurcates, with one branch yielding mid-B to late-F hypergiants, and cool supergiants, and the other massive blue stragglers prior to a diverse population of H-depleted WRs. We identify a substantial population of O-type stars with very broad Paschen series lines, a morphology that is directly comparable to known binaries in the cluster. In a few cases additional low-resolution R-band spectroscopy is available, revealing double-lined He I profiles and confirming binarity for these objects; suggesting a correspondingly high binary fraction amongst relatively unevolved cluster members. Conclusions. Our current census remains incomplete, but indicates that Westerlund 1 contains at least 166 stars with initial masses estimated to lie between ∼25 M⊙ and ∼50 M⊙, with more massive stars already lost to supernova. Our data is consistent with the cluster being co-eval, although binary interaction is clearly required to yield the observed stellar population, which is characterised by a uniquely rich cohort of hypergiants ranging from spectral type O to F, with both mass-stripped primaries and rejuvenated secondaries or merger products present. Future observations of Wd1 and similar stellar aggregates hold out the prospect of characterising both single- and binary- evolutionary channels for massive stars and determining their relative contributions. This in turn will permit the physical properties of such objects at the point of core-collapse to be predicted, which is of direct relevance for understanding the formation of relativistic remnants such as the magnetars associated with Wd1 and other young massive clusters.

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The episodic and multiscale Galactic Centre

Bryant

Krabbe

2021

New Astronomy Reviews

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An updated stellar census of the Quintuplet cluster

Cited by 37 publications

References 122 publications

The Arches cluster revisited

The Arches cluster revisited

A VLT/FLAMES survey for massive binaries in Westerlund 1

The episodic and multiscale Galactic Centre

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