Mass segregation and sequential star formation in NGC 2264 revealed by Herschel

AbstractWe derived proper motions and membership probabilities of stars in the regions of two very young (~ 2–4 Myr-old) open clusters NGC 2244 and NGC 6530. Both clusters show clear evidence of mass segregation, which provides strong support for the suggestion that the observed mass segregation is – at least partially – due to the way in which star formation has proceeded in these complex star-forming regions (“primordial” mass segregation).

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Primordial mass segregation in simulations of star formation?

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/stu2393 ◽

2014 ◽

Vol 446 (4) ◽

pp. 4278-4290 ◽

Cited By ~ 19

Author(s):

Richard J. Parker ◽

James E. Dale ◽

Barbara Ercolano

Keyword(s):

Star Formation ◽

Mass Segregation

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Star formation activity and the spatial distribution and mass segregation of dense cores in the early phases of star formation

Astronomy and Astrophysics ◽

10.1051/0004-6361/201834080 ◽

2019 ◽

Vol 629 ◽

pp. A135 ◽

Cited By ~ 7

Author(s):

Sami Dib ◽

Thomas Henning

Keyword(s):

Spatial Distribution ◽

Star Formation ◽

Large Scale ◽

Nearby Star ◽

Star Forming ◽

Star Forming Regions ◽

Dense Cores ◽

Star Formation Activity ◽

Mass Segregation ◽

Massive Cores

We examine the spatial distribution and mass segregation of dense molecular cloud cores in a number of nearby star forming regions (the region L1495 in Taurus, Aquila, Corona Australis, and W43) that span about four orders of magnitude in star formation activity. We used an approach based on the calculation of the minimum spanning tree, and for each region, we calculated the structure parameter 𝒬 and the mass segregation ratio ΛMSR measured for various numbers of the most massive cores. Our results indicate that the distribution of dense cores in young star forming regions is very substructured and that it is very likely that this substructure will be imprinted onto the nascent clusters that will emerge out of these clouds. With the exception of Taurus in which there is nearly no mass segregation, we observe mild-to-significant levels of mass segregation for the ensemble of the 6, 10, and 14 most massive cores in Aquila, Corona Australis, and W43, respectively. Our results suggest that the clouds’ star formation activity are linked to their structure, as traced by their population of dense cores. We also find that the fraction of massive cores that are the most mass segregated in each region correlates with the surface density of star formation in the clouds. The Taurus region with low star forming activity is associated with a highly hierarchical spatial distribution of the cores (low 𝒬 value) and the cores show no sign of being mass segregated. On the other extreme, the mini-starburst region W43-MM1 has a higher 𝒬 that is suggestive of a more centrally condensed structure. Additionally, it possesses a higher fraction of massive cores that are segregated by mass. While some limited evolutionary effects might be present, we largely attribute the correlation between the star formation activity of the clouds and their structure to a dependence on the physical conditions that have been imprinted on them by the large scale environment at the time they started to assemble.

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Disruption of Hierarchical Clustering in the Vela OB2 Complex and the Cluster Pair Collinder 135 and UBC 7 with Gaia EDR3: Evidence of Supernova Quenching

The Astrophysical Journal ◽

10.3847/1538-4357/ac2838 ◽

2021 ◽

Vol 923 (1) ◽

pp. 20

Author(s):

Xiaoying Pang ◽

Zeqiu Yu ◽

Shih-Yun Tang ◽

Jongsuk Hong ◽

Zhen Yuan ◽

...

Keyword(s):

Star Formation ◽

Learning Algorithm ◽

Hierarchical Structures ◽

Supernova Explosion ◽

Local Cluster ◽

Stellar Feedback ◽

Manual Intervention ◽

Mass Segregation ◽

Upper Rim ◽

Cluster Pair

Abstract We identify hierarchical structures in the Vela OB2 complex and the cluster pair Collinder 135 and UBC 7 with Gaia EDR3 using the neural network machine-learning algorithm StarGO. Five second-level substructures are disentangled in Vela OB2, which are referred to as Huluwa 1 (Gamma Velorum), Huluwa 2, Huluwa 3, Huluwa 4, and Huluwa 5. For the first time, Collinder 135 and UBC 7 are simultaneously identified as constituent clusters of the pair with minimal manual intervention. We propose an alternative scenario in which Huluwa 1–5 have originated from sequential star formation. The older clusters Huluwa 1–3, with an age of 10–22 Myr, generated stellar feedback to cause turbulence that fostered the formation of the younger-generation Huluwa 4–5 (7–20 Myr). A supernova explosion located inside the Vela IRAS shell quenched star formation in Huluwa 4–5 and rapidly expelled the remaining gas from the clusters. This resulted in global mass stratification across the shell, which is confirmed by the regression discontinuity method. The stellar mass in the lower rim of the shell is 0.32 ± 0.14 M ⊙ higher than in the upper rim. Local, cluster-scale mass segregation is observed in the lowest-mass cluster Huluwa 5. Huluwa 1–5 (in Vela OB2) are experiencing significant expansion, while the cluster pair suffers from moderate expansion. The velocity dispersions suggest that all five groups (including Huluwa 1A and Huluwa 1B) in Vela OB2 and the cluster pair are supervirial and are undergoing disruption, and also that Huluwa 1A and Huluwa 1B may be a coeval young cluster pair. N-body simulations predict that Huluwa 1–5 in Vela OB2 and the cluster pair will continue to expand in the future 100 Myr and eventually dissolve.

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THE IMPACT OF MASS SEGREGATION AND STAR FORMATION ON THE RATES OF GRAVITATIONAL-WAVE SOURCES FROM EXTREME MASS RATIO INSPIRALS

The Astrophysical Journal ◽

10.3847/2041-8205/830/1/l1 ◽

2016 ◽

Vol 830 (1) ◽

pp. L1 ◽

Cited By ~ 18

Author(s):

Danor Aharon ◽

Hagai B. Perets

Keyword(s):

Star Formation ◽

Gravitational Wave ◽

Mass Ratio ◽

Mass Segregation ◽

The Impact

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Distribution of Serpens South protostars revealed with ALMA

Astronomy and Astrophysics ◽

10.1051/0004-6361/201732372 ◽

2018 ◽

Vol 615 ◽

pp. A9 ◽

Cited By ~ 16

Author(s):

Adele L. Plunkett ◽

Manuel Fernández-López ◽

Héctor G. Arce ◽

Gemma Busquet ◽

Diego Mardones ◽

...

Keyword(s):

Star Formation ◽

Minimum Spanning Tree ◽

Cluster Center ◽

Mass Star ◽

Filamentary Structure ◽

First Case ◽

Low Mass ◽

Mass Segregation ◽

The Masses ◽

Mass Sources

Context. Clusters are common sites of star formation, whose members display varying degrees of mass segregation. The cause may be primordial or dynamical, or a combination both. If mass segregation were to be observed in a very young protostellar cluster, then the primordial case can be assumed more likely for that region. Aims. We investigated the masses and spatial distributions of pre-stellar and protostellar candidates in the young, low-mass star forming region Serpens South, where active star formation is known to occur along a predominant filamentary structure. Previous observations used to study these distributions have been limited by two important observational factors: (1) sensitivity limits that leave the lowest-mass sources undetected or (2) resolution limits that cannot distinguish binaries and/or cluster members in close proximity. Methods. Recent millimeter-wavelength interferometry observations can now uncover faint and/or compact sources in order to study a more complete population of protostars, especially in nearby (D < 500 pc) clusters. Here we present ALMA observations of 1 mm (Band 6) continuum in a 3 × 2 arcmin region at the center of Serpens South. Our angular resolution of ~1′′ is equivalent to ~400 au, corresponding to scales of envelopes and/or disks of protostellar sources. Results. We detect 52 sources with 1 mm continuum, and we measure masses of 0.002–0.9 solar masses corresponding to gas and dust in the disk and/or envelope of the protostellar system. For the deeply embedded (youngest) sources with no IR counterparts, we find evidence of mass segregation and clustering according to: the minimum spanning tree method, distribution of projected separations between unique sources, and concentration of higher-mass sources near to the dense gas at the cluster center. Conclusions. The mass segregation of the mm sources is likely primordial rather than dynamical given the young age of this cluster, compared with segregation time. This is the first case to show this for mm sources in a low-mass protostellar cluster environment.

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