Filamentary Fragmentation and Accretion in High-mass Star-forming Molecular Clouds

Lu, Xing; Zhang, Qizhou; Liu, Hauyu Baobab; Sanhueza, Patricio; Tatematsu, Ken’ichi; Feng, Siyi; Smith, H. A.; Myers, Philip C.; Sridharan, T. K.; Gu, Qiusheng

doi:10.3847/1538-4357/aaad11

Cited by 111 publications

(117 citation statements)

References 106 publications

(162 reference statements)

Supporting

Mentioning

106

Contrasting

Order By: Relevance

“…A similar situation has also been seen in W43-MM1 (see Paper I and Motte et al 2018). Additional examples from other highmass star forming regions have been presented in the literature (Lu et al 2018;Sanhueza et al 2017;Cyganowski et al 2017;Zhang et al 2015;Frau et al 2014). This indicates that low mass stars are also being formed along high-mass stars and therefore, low mass and high mass star formation processes might be coupled.…”

Section: Infalling Motionssupporting

confidence: 77%

The Seven Most Massive Clumps in W43-Main as Seen by ALMA: Dynamical Equilibrium and Magnetic Fields

Cortés

Hull

Girart

et al. 2019

ApJ

View full text Add to dashboard Cite

Here we present new ALMA observations of polarized dust emission from six of the most massive clumps in W43-Main. The clumps MM2, MM3, MM4, MM6, MM7, and MM8, have been resolved into two populations of fragmented filaments. From these two populations we extracted 81 cores (96 with the MM1 cores) with masses between 0.9 M to 425 M and a mass sensitivity of 0.08 M . The MM6, MM7, and MM8 clumps show significant fragmentation, but the polarized intensity appears to be sparse and compact. The MM2, MM3, and MM4 population shows less fragmentation, but with a single proto-stellar core dominating the emission at each clump. Also, the polarized intensity is more extended and significantly stronger in this population. From the polarized emission, we derived detailed magnetic field patterns throughout the filaments which we used to estimate field strengths for 4 out of the 6 clumps. The average field strengths estimations were found between 500 µG to 1.8 mG. Additionally, we detected and modeled infalling motions towards MM2 and MM3 from single dish HCO + (J = 4 → 3) and HCN(J = 4 → 3) data resulting in mass infall rates oḟ M MM2 = 1.2 × 10 −2 M yr −1 andṀ MM3 = 6.3 × 10 −3 M yr −1 . By using our estimations, we evaluated the dynamical equilibrium of our cores by computing the total virial parameter α total . For the cores with reliable field estimations, we found that 71% of them appear to be gravitationally bound while the remaining 29% are not. We concluded that these unbound cores, also less massive, are still accreting and have not yet reached a critical mass. This also implies different evolutionary time-scales, which essentially suggests that star-formation in high mass filaments is not uniform.

show abstract

Section: Infalling Motionssupporting

confidence: 77%

The Seven Most Massive Clumps in W43-Main as Seen by ALMA: Dynamical Equilibrium and Magnetic Fields

Cortés

Hull

Girart

et al. 2019

ApJ

View full text Add to dashboard Cite

show abstract

“…We choose 'fractal' initial conditions (ICs) for an initial distribution of stars in a cluster to model a complex initial distribution. Stars seem often to form in clumpy and filamentary substructures (Könyves et al 2015;Lu et al 2018;Parker 2018;Dib & Henning 2019). Note that we are not claiming that this is a match to how GMCs actually produce stars, rather it is a simple method for making (sub)structured initial conditions that are closer to reality that the classic Plummer sphere.…”

Section: Initial Position and Velocity Structuresmentioning

confidence: 96%

Making top-heavy IMFs from canonical IMFs near the Galactic Centre

Park

Goodwin

Kim

2020

Monthly Notices of the Royal Astronomical Society

View full text Add to dashboard Cite

We show that dynamical evolution in a strong (Galactic Centre-like) tidal field can create clusters that would appear to have very top-heavy IMFs. The tidal disruption of single star forming events can leave several bound 'clusters' spread along 20 pc of the orbit within 1-2 Myr. These surviving (sub)clusters tend to contain an over-abundance of massive stars, with low-mass stars tending to be spread along the whole 'tidal arm'. Therefore observing a cluster in a strong tidal field with a top-heavy IMF might well not mean the stars formed with a top-heavy IMF.

show abstract

“…Our observations with spatial resolution of ∼0.03 pc, ten times smaller than that of Csengeri et al (2017), show that the number of cores per clump increases to 10, suggesting that we are resolving further fragmentation within MDCs. Recent studies of clumps with similar characteristics to those observed by Csengeri et al (2017) have reported levels of fragmentation ranging from 5 to 20 cores when observed at scales of 0.03-0.05 pc (eg., Lu et al 2018;Contreras et al 2018). Figure 19 shows the normalized cumulative distribution function (CDF), also known as empirical cumulative distribution function (eCDF).…”

Section: Mass Distributionmentioning

confidence: 99%

ALMA Observations of Two Massive and Dense MALT90 Clumps

Neupane

Garay

Contreras

et al. 2020

ApJ

View full text Add to dashboard Cite

We report Atacama Large Millimeter Array observations of 3 mm dust continuum emission and line emission, in HCO + , H 13 CO + , N 2 H + and CH 3 CN, towards two massive and dense clumps (MDCs) in early but distinct evolutionary phases (prestellar and protostellar), made with the goal of investigating their fragmentation characteristics at angular scales of ∼1 . Towards the prestellar clump we detected ten compact structures (cores), with radius from 1200 to 4500 AU and masses from 1.6 to 20 M . Half of these cores exhibit inverse P Cygni profiles in HCO + and are subvirialized indicating that they are undergoing collapse. Towards the protostellar clump we detected a massive (119 M ) central core, with a strong mass infall rate, and nine less massive cores, with masses from 1.7 to 27 M and radius from 1000 to 4300 AU. CH 3 CN rotational tem-Corresponding author: S., Neupane

show abstract

Filamentary Fragmentation and Accretion in High-mass Star-forming Molecular Clouds

Cited by 111 publications

References 106 publications

The Seven Most Massive Clumps in W43-Main as Seen by ALMA: Dynamical Equilibrium and Magnetic Fields

The Seven Most Massive Clumps in W43-Main as Seen by ALMA: Dynamical Equilibrium and Magnetic Fields

Making top-heavy IMFs from canonical IMFs near the Galactic Centre

ALMA Observations of Two Massive and Dense MALT90 Clumps

Contact Info

Product

Resources

About