The inception of star cluster formation revealed by [C <scp>ii</scp>] emission around an Infrared Dark Cloud

Bisbas, Thomas G.; Tan, Jonathan C.; Csengeri, T.; Wu, Benjamin; Lim, Wanggi; Caselli, P.; Güsten, R.; Ricken, Oliver; Riquelme, D.

doi:10.1093/mnrasl/sly039

Cited by 22 publications

(24 citation statements)

References 36 publications

(40 reference statements)

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“…Bisbas et al (2017) used radiative transfer calculations to show that the [CII] and CO lines show a significant offset in the process of the cloud collision. Such an offset is reported toward a few possible cloud-cloud collision sites (Bisbas et al 2018;Lim and De Buizer 2019). Nonetheless, it needs to be quantified how this signature differs from hierarchical gravitational collapse or feedback-driven outflows.…”

Section: High-mass Star Formation Triggered By Cloud-cloud Collisionsmentioning

confidence: 99%

The Molecular Cloud Lifecycle

et al. 2020

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Giant molecular clouds (GMCs) and their stellar offspring are the building blocks of galaxies. The physical characteristics of GMCs and their evolution are tightly connected to galaxy evolution. The macroscopic properties of the interstellar medium propagate into the properties of GMCs condensing out of it, with correlations between e.g. the galactic and GMC scale gas pressures, surface densities and volume densities. That way, the galactic environment sets the initial conditions for star formation within GMCs. After the onset of massive star formation, stellar feedback from e.g. photoionisation, stellar winds, and supernovae eventually contributes to dispersing the parent cloud, depositing energy, momentum and metals into the surrounding medium, thereby changing the properties of galaxies. This cycling of matter between gas and stars, governed by star formation and feedback, is therefore a major driver of galaxy evolution. Much of the recent debate has focused on the durations of the various evolutionary phases that constitute this cycle in galaxies, and what these can teach us about the physical mechanisms driving the cycle. We review results from observational, theoretical, and numerical work to build a dynamical picture of the evolutionary lifecycle of GMC evolution, star formation, and feedback in galaxies.

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Section: High-mass Star Formation Triggered By Cloud-cloud Collisionsmentioning

confidence: 99%

The Molecular Cloud Lifecycle

et al. 2020

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“…This scenario was originally suggested by Mufson & Liszt (1977) based on molecular and recombination line observations, with follow-up studies supporting the idea (e.g., Buckley & Ward-Thompson 1996;Serabyn et al 1993). Unfortunately, our data cannot prove such a scenario, and more direct evidence of the cloud-cloud collision scenario will need targeted observations, such as comparing velocity profiles of the 158 µm [C II] line emission and CO isotopologue bands (Bisbas et al 2018;Lim et al 2021). However, such a global-triggering scenario could explain why so many sub-regions spread throughout such a large volume could have begun star-formation activities at the same time.…”

Section: The History Of Stellar Cluster Formation In W49amentioning

confidence: 53%

Surveying the Giant HII Regions of the Milky Way with SOFIA: III. W49A

De Buizer,

Lim,

Liu

et al. 2021

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We present our third set of results from our mid-infrared imaging survey of Milky Way Giant H II regions with our detailed analysis of W49A, one of the most distant, yet most luminous, GH II regions in the Galaxy. We used the FORCAST instrument on the Stratospheric Observatory For Infrared Astronomy (SOFIA) to obtain 20 and 37 µm images of the entire ∼5.0 × 3.5 infrared-emitting area of W49A at a spatial resolution of ∼3 . Utilizing these SOFIA data in conjunction with previous multiwavelength observations from the near-infrared to radio, including Spitzer-IRAC and Herschel-PACS archival data, we investigate the physical nature of individual infrared sources and sub-components within W49A. For individual compact sources we used the multi-wavelength photometry data to construct spectral energy distributions (SEDs) and fit them with massive young stellar object (MYSO) SED models, and find 22 sources that are likely to be MYSOs. Ten new sources are identified for the first time in this work. Even at 37 µm we are unable to detect infrared emission from the sources on the western side of the extremely extinguished ring of compact radio emission sources known as the Welch Ring. Utilizing multi-wavelength data, we derived luminosity-to-mass ratio and virial parameters of the extended radio sub-regions of W49A to estimate their relative ages and find that overall the sub-components of W49A have a very small spread in evolutionary state compared to our previously studied GH II regions.

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“…3.2 Comparing 13 CO(1-0) to [Cii] 158 µm Bisbas et al (2018) detected velocity and position offsets between [Cii] 158 µm and 13 CO (1-0) line emission maps in IRDC G035.39-00.33. From a comparison with results of numerical models, they claimed that a cloudcloud collision could explain these offsets, and thus may be a likely formation mechanism for the IRDC.…”

Section: Probability Distribution Functions Of the Velocitiesmentioning

confidence: 99%

“…One needs to note that Bisbas et al (2018) predicted position offsets between 13 CO and [Cii] emission which are not distinguishable in the integrated line images. The detailed 13 CO and [Cii] structures enable us to investigate through a pixel by pixel comparison of both line emissions.…”

Section: Probability Distribution Functions Of the Velocitiesmentioning

confidence: 99%

“…However, these studies have typically been limited to searching for the "bridge effect" (Haworth et al 2015;Bisbas et al 2017) in positionvelocity diagrams from molecular gas tracers, such as 12 CO(1-0). Recently, Bisbas et al (2018) introduced a new method to test the observational evidence of GMC collisions by examining both 13 CO(1-0) emission (from the Galactic Ring Survey [GRS]; Jackson et al 2006) and 158µm [Cii] emission (from SOFIA-upGREAT) toward an IRDC. They found position and velocity offsets between 13 CO(1-0) and [Cii] intensity peaks of IRDC G035.39-00.33, to be consistent with those derived in simulations and synthetic observations of cloud-cloud collisions.…”

Section: Introductionmentioning

confidence: 99%

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Star Cluster Formation in Orion A

Lim,

Nakamura,

et al. 2020

Preprint

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We introduce new analysis methods for studying the star cluster formation processes in Orion A, especially examining the scenario of a cloud-cloud collision. We utilize the CARMA-NRO Orion survey 13 CO (1-0) data to compare molecular gas to the properties of YSOs from the SDSS III IN-SYNC survey. We show that the increase of v 13CO − v YSO and Σ scatter o older YSOs can be signals of cloud-cloud collision. SOFIA-upGREAT 158µm [Cii] archival data toward the northern part of Orion A are also compared to the 13 CO data to test whether the position and velocity offsets between the emission from these two transitions resemble those predicted by a cloud-cloud collision model. We find that the northern part of Orion A, including regions ONC-OMC-1, OMC-2, OMC-3 and OMC-4, shows qualitative agreements with the cloud-cloud collision scenario, while in one of the southern regions, NGC1999, there is no indication of such a process in causing the birth of new stars. On the other hand, another southern cluster, L1641N, shows slight tendencies of cloud-cloud collision. Overall, our results support the cloud-cloud collision process as being an important mechanism for star cluster formation in Orion A.

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The inception of star cluster formation revealed by [C ii] emission around an Infrared Dark Cloud

Cited by 22 publications

References 36 publications

The Molecular Cloud Lifecycle

The Molecular Cloud Lifecycle

Surveying the Giant HII Regions of the Milky Way with SOFIA: III. W49A

Star Cluster Formation in Orion A

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