MAGNETIC FIELD PROPERTIES IN HIGH-MASS STAR FORMATION FROM LARGE TO SMALL SCALES: A STATISTICAL ANALYSIS FROM POLARIZATION DATA

Abstract A supersonic cloud–cloud collision produces a shock-compressed layer which leads to formation of high-mass stars via gravitational instability. We carried out a detailed analysis of the layer by using the numerical simulations of magneto-hydrodynamics which deal with colliding molecular flows at a relative velocity of 20 km s−1 (Inoue & Fukui 2013, ApJ, 774, L31). Maximum density in the layer increases from 1000 cm−3 to more than 105 cm−3 within 0.3 Myr by compression, and the turbulence and the magnetic field in the layer are amplified by a factor of ∼5, increasing the mass accretion rate by two orders of magnitude to more than 10−4 $ M_{\odot } $ yr−1. The layer becomes highly filamentary due to gas flows along the magnetic field lines, and dense cores are formed in the filaments. The massive dense cores have size and mass of 0.03–0.08 pc and 8–$ 50\, M_{\odot } $ and they are usually gravitationally unstable. The mass function of the dense cores is significantly top-heavy as compared with the universal initial mass function, indicating that the cloud–cloud collision preferentially triggers the formation of O and early B stars. We argue that the cloud–cloud collision is a versatile mechanism which creates a variety of stellar clusters from a single O star like RCW 120 and M 20 to tens of O stars of a super star cluster like RCW 38 and a mini-starburst W 43. The core mass function predicted by the present model is consistent with the massive dense cores obtained by recent ALMA observations in RCW 38 (Torii et al. 2021, PASJ, in press) and W 43 (Motte et al. 2018, Nature Astron., 2, 478). Considering the increasing evidence for collision-triggered high-mass star formation, we argue that cloud–cloud collision is a major mechanism of high-mass star formation.

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Magnetic fields at the onset of high-mass star formation

Astronomy and Astrophysics ◽

10.1051/0004-6361/201732378 ◽

2018 ◽

Vol 614 ◽

pp. A64 ◽

Cited By ~ 12

Author(s):

H. Beuther ◽

J. D. Soler ◽

W. Vlemmings ◽

H. Linz ◽

Th. Henning ◽

...

Keyword(s):

Magnetic Field ◽

Star Formation ◽

Magnetic Fields ◽

Spectral Line ◽

Function Analysis ◽

High Mass ◽

Mass Star ◽

Starting Point ◽

Polarized Emission ◽

The Magnetic Field

Context. The importance of magnetic fields at the onset of star formation related to the early fragmentation and collapse processes is largely unexplored today. Aims. We want to understand the magnetic field properties at the earliest evolutionary stages of high-mass star formation. Methods. The Atacama Large Millimeter Array is used at 1.3 mm wavelength in full polarization mode to study the polarized emission, and, using this, the magnetic field morphologies and strengths of the high-mass starless region IRDC 18310-4. Results. Polarized emission is clearly detected in four sub-cores of the region; in general it shows a smooth distribution, also along elongated cores. Estimating the magnetic field strength via the Davis-Chandrasekhar-Fermi method and following a structure function analysis, we find comparably large magnetic field strengths between ~0.3–5.3 mG. Comparing the data to spectral line observations, the turbulent-to-magnetic energy ratio is low, indicating that turbulence does not significantly contribute to the stability of the gas clump. A mass-to-flux ratio around the critical value 1.0 – depending on column density – indicates that the region starts to collapse, which is consistent with the previous spectral line analysis of the region. Conclusions. While this high-mass region is collapsing and thus at the verge of star formation, the high magnetic field values and the smooth spatial structure indicate that the magnetic field is important for the fragmentation and collapse process. This single case study can only be the starting point for larger sample studies of magnetic fields at the onset of star formation.

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High-mass star formation at sub-50 au scales

Astronomy and Astrophysics ◽

10.1051/0004-6361/201834064 ◽

2019 ◽

Vol 621 ◽

pp. A122 ◽

Cited By ~ 12

Author(s):

H. Beuther ◽

A. Ahmadi ◽

J. C. Mottram ◽

H. Linz ◽

L. T. Maud ◽

...

Keyword(s):

Star Formation ◽

Optical Depth ◽

Spatial Resolution ◽

Velocity Structure ◽

Spatial Scales ◽

Spectral Lines ◽

Emission Lines ◽

High Mass ◽

Mass Star ◽

Small Scales

Context. The hierarchical process of star formation has so far mostly been studied on scales from thousands of au to parsecs, but the smaller sub-1000 au scales of high-mass star formation are still largely unexplored in the submillimeter regime. Aims. We aim to resolve the dust and gas emission at the highest spatial resolution to study the physical properties of the densest structures during high-mass star formation. Methods. We observed the high-mass hot core region G351.77-0.54 with the Atacama Large Millimeter Array with baselines extending out to more than 16 km. This allowed us to dissect the region at sub-50 au spatial scales. Results. At a spatial resolution of 18/40 au (depending on the distance), we identify twelve sub-structures within the inner few thousand au of the region. The brightness temperatures are high, reaching values greater 1000 K, signposting high optical depth toward the peak positions. Core separations vary between sub-100 au to several 100 and 1000 au. The core separations and approximate masses are largely consistent with thermal Jeans fragmentation of a dense gas core. Due to the high continuum optical depth, most spectral lines are seen in absorption. However, a few exceptional emission lines are found that most likely stem from transitions with excitation conditions above 1000 K. Toward the main continuum source, these emission lines exhibit a velocity gradient across scales of 100–200 au aligned with the molecular outflow and perpendicular to the previously inferred disk orientation. While we cannot exclude that these observational features stem from an inner hot accretion disk, the alignment with the outflow rather suggests that it stems from the inner jet and outflow region. The highest-velocity features are found toward the peak position, and no Hubble-like velocity structure can be identified. Therefore, these data are consistent with steady-state turbulent entrainment of the hot molecular gas via Kelvin–Helmholtz instabilities at the interface between the jet and the outflow. Conclusions. Resolving this high-mass star-forming region at sub-50 au scales indicates that the hierarchical fragmentation process in the framework of thermal Jeans fragmentation can continue down to the smallest accessible spatial scales. Velocity gradients on these small scales have to be treated cautiously and do not necessarily stem from disks, but may be better explained with outflow emission. Studying these small scales is very powerful, but covering all spatial scales and deriving a global picture from large to small scales are the next steps to investigate.

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Revealing magnetic fields towards massive protostars: a multi-scale approach using masers and dust

Proceedings of the International Astronomical Union ◽

10.1017/s1743921319003661 ◽

2018 ◽

Vol 14 (A30) ◽

pp. 111-112

Author(s):

Daria Dall’Olio ◽

W. H. T. Vlemmings ◽

M. V. Persson

Keyword(s):

Magnetic Field ◽

Star Formation ◽

Magnetic Fields ◽

Spatial Scales ◽

High Mass ◽

Small Scale ◽

Evolutionary Stage ◽

Mass Star ◽

Filamentary Structure ◽

The Magnetic Field

AbstractMagnetic fields play a significant role during star formation processes, hindering the fragmentation and the collapse of the parental cloud, and affecting the accretion mechanisms and feedback phenomena. However, several questions still need to be addressed to clarify the importance of magnetic fields at the onset of high-mass star formation, such as how strong they are and at what evolutionary stage and spatial scales their action becomes relevant. Furthermore, the magnetic field parameters are still poorly constrained especially at small scales, i.e. few astronomical units from the central object, where the accretion disc and the base of the outflow are located. Thus we need to probe magnetic fields at different scales, at different evolutionary steps and possibly with different tracers. We show that the magnetic field morphology around high-mass protostars can be successfully traced at different scales by observing maser and dust polarised emission. A confirmation that they are effective tools is indeed provided by our recent results from 6.7 GHz MERLIN observations of the massive protostar IRAS 18089-1732, where we find that the small-scale magnetic field probed by methanol masers is consistent with the large-scale magnetic field probed by dust (Dall’Olio et al. 2017 A&A 607, A111). Moreover we present results obtained from our ALMA Band 7 polarisation observations of G9.62+0.20, which is a massive star-forming region with a sequence of cores at different evolutionary stages (Dall’Olio et al. submitted to A&A). In this region we resolve several protostellar cores embedded in a bright and dusty filamentary structure. The magnetic field morphology and strength in different cores is related to the evolutionary sequence of the star formation process which is occurring across the filament.

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Magnetic massive stars in star forming regions

Proceedings of the International Astronomical Union ◽

10.1017/s174392131900382x ◽

2018 ◽

Vol 14 (A30) ◽

pp. 132-132

Author(s):

Swetlana Hubrig ◽

Markus Schöller ◽

Silva P. Järvinen

Keyword(s):

Magnetic Field ◽

Star Formation ◽

Magnetic Fields ◽

Active Sites ◽

Massive Stars ◽

High Mass ◽

Mass Star ◽

Star Forming ◽

Star Forming Regions ◽

Gas Cloud

AbstractOne idea for the origin of magnetic fields in massive stars suggests that the magnetic field is the fossil remnant of the Galactic ISM magnetic field, amplified during the collapse of the magnetised gas cloud. A search for the presence of magnetic fields in massive stars located in active sites of star formation led to the detection of rather strong magnetic fields in a few young stars. Future spectropolarimetric observations are urgently needed to obtain insights into the mechanisms that drive the generation of kG magnetic fields during high-mass star formation.

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Gravity-driven Magnetic Field at ∼1000 au Scales in High-mass Star Formation

The Astrophysical Journal ◽

10.3847/2041-8213/ac081c ◽

2021 ◽

Vol 915 (1) ◽

pp. L10

Author(s):

Patricio Sanhueza ◽

Josep Miquel Girart ◽

Marco Padovani ◽

Daniele Galli ◽

Charles L. H. Hull ◽

...

Keyword(s):

Magnetic Field ◽

Star Formation ◽

High Mass ◽

Mass Star ◽

Gravity Driven

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Statistical analysis of the physical properties of the 6.7 GHz methanol maser features based on VLBI data

Proceedings of the International Astronomical Union ◽

10.1017/s1743921317009425 ◽

2017 ◽

Vol 13 (S336) ◽

pp. 321-322 ◽

Cited By ~ 1

Author(s):

R. Sarniak ◽

M. Szymczak ◽

A. Bartkiewicz

Keyword(s):

Statistical Analysis ◽

Star Formation ◽

Physical Properties ◽

Angular Resolution ◽

High Mass ◽

High Angular Resolution ◽

Mass Star ◽

Methanol Maser ◽

Vlbi Data ◽

Methanol Masers

AbstractMethanol masers observed at high angular resolution are useful tool to investigate the processes of high-mass star formation. Here, we present the results of statistical analysis of the 6.7 GHz methanol maser structures in 60 sources observed with the EVN. The parameters of the maser clouds and exciting stars were derived. There is evidence that the emission structures composed of larger number of maser clouds are formed in the vicinity of more luminous exciting stars.

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Gravity and Rotation Drag the Magnetic Field in High-mass Star Formation

The Astrophysical Journal ◽

10.3847/1538-4357/abc019 ◽

2020 ◽

Vol 904 (2) ◽

pp. 168

Author(s):

Henrik Beuther ◽

Juan D. Soler ◽

Hendrik Linz ◽

Thomas Henning ◽

Caroline Gieser ◽

...

Keyword(s):

Magnetic Field ◽

Star Formation ◽

High Mass ◽

Mass Star ◽

The Magnetic Field

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MAGMO: Mapping the Galactic Magnetic field through OH masers

Proceedings of the International Astronomical Union ◽

10.1017/s1743921314011715 ◽

2012 ◽

Vol 10 (H16) ◽

pp. 402-402 ◽

Cited By ~ 1

Author(s):

James A. Green ◽

Naomi M. McClure-Griffiths ◽

James L. Caswell ◽

Tim Robishaw ◽

Lisa Harvey-Smith ◽

...

Keyword(s):

Magnetic Field ◽

Star Formation ◽

Magnetic Fields ◽

Ground State ◽

Large Scale ◽

Zeeman Splitting ◽

High Mass ◽

Mass Star ◽

Galactic Magnetic Field ◽

Maser Emission

AbstractWe are undertaking a project (MAGMO) to examine large-scale magnetic fields pervading regions of high-mass star formation. The project will test if the orientations of weak large-scale magnetic fields can be maintained in the contraction (and field amplification) to the high densities encountered in high-mass star forming regions. This will be achieved through correlating targeted observations of ground-state hydroxyl (OH) maser emission towards hundreds of sites of high-mass star formation spread throughout the spiral arms of the Milky Way. Through the Zeeman splitting of the OH maser emission these observations will determine the strength and orientation of the in-situ magnetic field. The completion of the southern hemisphere Methanol Multibeam survey has provided an abundance of targets for ground-state OH maser observations, approximately 1000 sites of high-mass star formation. With this sample, much larger and more homogeneous than previously available, we will have the statistics necessary to outweigh random fluctuations and observe an underlying Galactic magnetic field if it exists. We presented details of the overall progress of the project illustrated by the results of a pilot sample of sources towards the Carina-Sagittarius spiral arm tangent, where a coherent field is implied.

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