Extreme star formation in the Milky Way: luminosity distributions of young stellar objects in W49A and W51

Eden, David; Moore, T. J. T.; Urquhart, J. S.; Elia, D.; Plume, R.; König, C.; Baldeschi, A.; Schisano, E.; Rigby, Andrew; Morgan, L. K.

doi:10.1093/mnras/sty606

Cited by 11 publications

(10 citation statements)

References 98 publications

(155 reference statements)

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“…This is consistent with the results of Eden et al (2015), who found an increased ratio of L/M, a proxy of SFE (e.g. Moore et al 2012;Eden et al 2015Eden et al , 2018, in the Perseus arm compared to the Scutum-Centaurus and Sagittarius spiral arms. However, this was found to be due to distinctly different time gradients for star formation across the spiral arms, with the Perseus star formation at a more advanced stage.…”

Section: Star Formation Across Different Spiral Armssupporting

confidence: 92%

Characteristic scale of star formation – I. Clump formation efficiency on local scales

Eden

Moore

Plume

et al. 2020

Monthly Notices of the Royal Astronomical Society

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We have used the ratio of column densities (CDR) derived independently from the 850-mum continuum JCMT Plane Survey (JPS) and the 13CO/C18O (J = 3 → 2) Heterodyne Inner Milky Way Plane Survey (CHIMPS) to produce maps of the dense-gas mass fraction (DGMF) in two slices of the Galactic Plane centred at ℓ = 30○ and ℓ = 40○. The observed DGMF is a metric for the instantaneous clump-formation efficiency (CFE) in the molecular gas. We split the two fields into velocity components corresponding to the spiral arms that cross them, and a two-dimensional power-spectrum analysis of the spiral arm DGMF maps reveals a break in slope at the approximate size scale of molecular clouds. We interpret this as the characteristic scale of the amplitude of variations in the CFE and a constraint on the dominant mechanism regulating the CFE and, hence, the star-formation efficiency in CO-traced clouds.

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Section: Star Formation Across Different Spiral Armssupporting

confidence: 92%

Characteristic scale of star formation – I. Clump formation efficiency on local scales

Eden

Moore

Plume

et al. 2020

Monthly Notices of the Royal Astronomical Society

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“…As the W49 region is known to contain significantly higher densities on smaller spatial scales that are not resolved by the observations presented in this work (e.g. Vastel et al 2001;Eden et al 2018). The line emission could then emit from these compact regions that are heavily beam diluted in the observations presented in this work.…”

Section: Focusing On the "Dense" Gas Within W49amentioning

confidence: 73%

“…Higher resolution observations have shown that much sub-structure exists within W49A on scales much smaller than this beam size, which would then not be resolved with these observations (Galván-Madrid et al 2013). For example, using James Clerk Maxwell Telescope and higher-resolution Herschel observations, Eden et al (2018) identified ∼ 50 compact sources within the central ∼ 60 pc of W49A that have effective radii ranging from 10−20 (∼ 0.2 -0.3 pc). These cores have masses of > 10 3 M , which when assuming a spherical geometry approximately have column densities of > 10 23 cm −2 .…”

Section: Caveatsmentioning

confidence: 94%

“…We propose that the number density using the spatial resolution of the Herschel observations can also be obtained by limiting the three-dimensional structure to a single spatial element along the line-of-sight: or in other words, by assuming that the measured column density at each position originates from a 20 × 20 × 20 cube (or ∼ 1 pc 3 at ∼ 11 kpc). We determine an uncertainty on the model density by varying the cube size by 1) the linear size based on the uncertainty from the distance estimate, and 2) varying the depth of the box between 0.5 − 3 pc, which represent the average size of the sub-structures identified by Eden et al (2018), and the size of the angular resolution of the molecular line observations (∼60 ), respectively.…”

Section: Focusing On the "Dense" Gas Within W49amentioning

confidence: 99%

“…Column density values of 10 23 cm −2 are only observed towards the centre of W49A within the ∼ 60 smoothed Herschel maps (see Figure 1). The dense region identified by Eden et al (2018) would then be beam diluted within our smoothed maps, along with any molecular line emission originating from these regions. It is plausible that this would cause molecular line emission predominately originating from isolated compact, high (column) dense regions to appear to originate from low column densities when diluted.…”

Section: Caveatsmentioning

confidence: 99%

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LEGO II: A 3 mm molecular line study covering 100 pc of one of the most actively star-forming portions within the Milky Way Disc

Barnes,

Kauffmann,

Bigiel

et al. 2020

Preprint

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The current generation of (sub)mm-telescopes has allowed molecular line emission to become a major tool for studying the physical, kinematic, and chemical properties of extragalactic systems, yet exploiting these observations requires a detailed understanding of where emission lines originate within the Milky Way. In this paper, we present 60 (∼ 3 pc) resolution observations of many 3mm-band molecular lines across a large map of the W49 massive star-forming region (∼ 100 × 100 pc at 11 kpc), which were taken as part of the "LEGO" IRAM-30m large project. We find that the spatial extent or brightness of the molecular line transitions are not well correlated with their critical densities, highlighting abundance and optical depth must be considered when estimating line emission characteristics. We explore how the total emission and emission efficiency (i.e. line brightness per H 2 column density) of the line emission vary as a function of molecular hydrogen column density and dust temperature. We find that there is not a single region of this parameter space responsible for the brightest and most efficiently emitting gas for all species. For example, we find that the HCN transition shows high emission efficiency at high column density (10 22 cm −2 ) and moderate temperatures (35 K), whilst e.g. N 2 H + emits most efficiently towards lower temperatures (10 22 cm −2 ; <20 K). We determine X CO(1−0) ∼ 0.3 × 10 20 cm −2 (K km s −1 ) −1 , and α HCN(1−0) ∼ 30 M (K km s −1 pc 2 ) −1 , which both differ significantly from the commonly adopted values. In all, these results suggest caution should be taken when interpreting molecular line emission.

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Near-infrared spectroscopy of the massive stellar population of W51: evidence for multi-seeded star formation

Bik

Henning

et al. 2019

A&A

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Context. The interplay between the formation of stars, stellar feedback and cloud properties strongly influences the star formation history of giant molecular clouds. The formation of massive stars leads to a variety of stellar clusters, ranging from low stellar density OB associations to dense, gravitationally bound starburst clusters. Aims. We aimed at identifying the massive stellar content and reconstructing the star formation history of the W51 giant molecular cloud.Methods. We performed near-infrared imaging and K-band spectroscopy of the massive stars in W51. We analyzed the stellar populations using colour-magnitude and colour-colour diagrams and compared the properties of the spectroscopically identified stars with stellar evolution models. Results. We derived the ages of the different sub-clusters in W51 and, based on our spectroscopy derived an age for W51 of 3 Myrs or less. The age of the P Cygni star LS1 and the presence of two still forming proto-clusters suggests that the star formation history of W51 is more complex than a single burst. Conclusions. We did not find evidence for triggered star formation and we concluded that the star formation in W51 is multi seeded. We finally concluded that W51 is a OB association where different sub-clusters form over a time span of at least 3-5 Myrs.

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Extreme star formation in the Milky Way: luminosity distributions of young stellar objects in W49A and W51

Cited by 11 publications

References 98 publications

Characteristic scale of star formation – I. Clump formation efficiency on local scales

Characteristic scale of star formation – I. Clump formation efficiency on local scales

LEGO II: A 3 mm molecular line study covering 100 pc of one of the most actively star-forming portions within the Milky Way Disc

Near-infrared spectroscopy of the massive stellar population of W51: evidence for multi-seeded star formation

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