On the evolution of a star cluster and its multiple stellar systems following gas dispersal

Moeckel, Nickolas; Bate, Matthew R.

doi:10.1111/j.1365-2966.2010.16347.x

Cited by 187 publications

(199 citation statements)

References 75 publications

(164 reference statements)

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“…Since star/cluster formation happens in a dynamic environment [6,2,28] it may be impossible to define what will become a stellar cluster in these early stages, as the final object that remains bound is simply the dynamically mixed part of a larger, initially hierarchical, distribution. In this scenario a cluster can only be clearly defined above the surrounding distribution once it is dynamically evolved where t age /t cross > 1, as defined by Gieles & Portegies Zwart 2010.…”

Section: Discussionmentioning

confidence: 99%

Do All Stars in the Solar Neighbourhood Form in Clusters?

Bressert

Bastian

Gutermuth

2011

Star Clusters in the Era of Large Surveys

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We present a global study of low mass, young stellar object (YSO) surface densities (Σ ) in nearby (< 500 pc) star forming regions based on a comprehensive collection of Spitzer Space Telescope surveys. We show that the distribution of YSO surface densities is a smooth distribution, being adequately described by a lognormal function from a few to 10 3 YSOs per pc 2 , with a peak at ∼ 22 stars pc −2 . The observed lognormal Σ is consistent with predictions of hierarchically structured starformation at scales below 10 pc, arising from the molecular cloud structures. We do not find evidence for multiple discrete modes of star-formation (e.g. clustered and distributed). Comparing the observed Σ distribution to previous Σ threshold definitions of clusters show that they are arbitrary. We find that only a low fraction (< 26%) of stars are formed in dense environments where their formation/evolution (along with their circumstellar disks and/or planets) may be affected by the close proximity of their low-mass neighbours.

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Section: Discussionmentioning

confidence: 99%

Do All Stars in the Solar Neighbourhood Form in Clusters?

Bressert

Bastian

Gutermuth

2011

Star Clusters in the Era of Large Surveys

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“…The initial densities for the smallest clusters seem a little extreme but there is increasing evidence that the initial densities of open clusters are higher than previously thought (Parker et al 2009), that bound clusters can expand quickly (Bastian et al 2008;Moeckel & Bate 2010) and that rapid expansion can occur in the core (Kroupa, Aarseth, & Hurley 2001). Indeed Table 2 shows that the densest clusters expand the most because of the longer dynamical time required and, interestingly, end up with very similar half-mass radii to clusters that were initially somewhat sparser.…”

Section: Densitiesmentioning

confidence: 99%

Pre-Mainsequence Stellar Evolution in N-Body Models

Railton

Tout

Aarseth

2014

Publ. Astron. Soc. Aust.

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We provide a set of analytic fits to the radii of pre-mainsequence stars in the mass range 0.1 < M/M ࣻ < 8.0. We incorporate the formulae in N-body cluster models for evolution from the beginning of pre-main sequence. In models with 1 000 stars and high initial cluster densities, pre-mainsequence evolution causes roughly twice the number of collisions between stars than in similar models with evolution begun only from the zero-age main sequence. The collisions are often all part of a runaway sequence that creates one relatively massive star.

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“…the PS's potential well, the sizes of the stellar orbits increase (e.g., Moeckel & Bate 2010;Decressin et al 2010;Trenti et al 2010, and references therein), and in this way the massive PSs can also more easily lose their stars. If the gas expulsion is inefficient -for instance, when the massive PS has a lower interaction with larger structures -the PS does not lose a large number of stars because the gas has been retained, thus ending up as a dwarf galaxy.…”

Section: Second Stage For Massive Pss (ω Cen's Progenitor)mentioning

confidence: 99%

“…after the expulsion of pristine gas, which leads to an expansion of the PS and a period of subsequent star loss (Moeckel & Bate 2010). Moreover, in a model where massive stars are considered to play an important role in the evolution of GCs, the formation of low-mass stars cannot be assumed to be instantaneous, because proto-low-mass stars have contraction times of several tens of Myr (Bernasconi & Maeder 1996), thus could become contaminated in that period of time by the winds of massive stars (Newsham & Terndrup 2007;Tsujimoto et al 2007).…”

Section: Required Improvementsmentioning

confidence: 99%

Formation of multiple populations in globular clusters: another possible scenario

Valcarce

Catelan

2011

A&A

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Aims. While spreads in chemical composition are now believed to be a universal characteristic of globular clusters (GCs), not all of them display evidence of multiple populations in their color-magnitude diagrams (CMDs). Here we present a new scenario for the formation of GCs, in an attempt to qualitatively explain these otherwise elusive observational results. Methods. Our scenario divides GCs into three groups, depending on the initial mass (M I ) of the progenitor structure (PS), as follows: i) massive PSs can retain the gas ejected by massive stars, including the ejecta of core-collapse SNe. ii) Intermediate-mass PSs can retain at least a fraction of the fast winds of massive stars, but none of the core-collapse SNe ejecta. iii) Low-mass PSs can only retain the slow winds of intermediate-mass stars. The first group would contain members such as ω Centauri (NGC 5139), M 54 (NGC 6715), M 22 (NGC 6656), and Terzan 5, whereas NGC 2808 (and possibly NGC 2419) would be members of the second group. The remaining GCs that have only a spread in light elements, such as O and Na, would be members of the third group. Results. According to our scenario, the different components of ω Cen should not have a sizeable spread in age. We argue that this is consistent with the available observations. We present other simple arguments in favor of our scenario, which can be described in terms of two main analytical relations: i) one between the actual observed ratio of the number of first to second generation stars (R FG SG ) and the fraction of first generation stars that have been lost by the GC (S L ) and ii) another between S L and M I . We also suggest a series of future improvements to and empirical tests of the modeling that may help decide whether the proposed scenario properly describes the chemical evolution of GCs.

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On the evolution of a star cluster and its multiple stellar systems following gas dispersal

Cited by 187 publications

References 75 publications

Do All Stars in the Solar Neighbourhood Form in Clusters?

Do All Stars in the Solar Neighbourhood Form in Clusters?

Pre-Mainsequence Stellar Evolution in N-Body Models

Formation of multiple populations in globular clusters: another possible scenario

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