Discs and outflows in the early phases of massive star formation: Influence of magnetic fields and ambipolar diffusion

AbstractThe role of the magnetic fields in the formation and quenching of stars with different mass is unknown. We studied the energy balance and the star formation efficiency in a sample of molecular clouds in the central kpc region of NGC 1097, known to be highly magnetized. Combining the full polarization VLA/radio continuum observations with the HST/Hα, Paα and the SMA/CO lines observations, we separated the thermal and non-thermal synchrotron emission and compared the magnetic, turbulent, and thermal pressures. Most of the molecular clouds are magnetically supported against gravitational collapse needed to form cores of massive stars. The massive star formation efficiency of the clouds also drops with the magnetic field strength, while it is uncorrelated with turbulence (Tabatabaei et al. 2018). The inefficiency of the massive star formation and the low-mass stellar population in the center of NGC 1097 can be explained in the following steps: I) Magnetic fields supporting the molecular clouds prevent the collapse of gas to densities needed to form massive stars. II) These clouds can then be fragmented into smaller pieces due to e.g., stellar feedback, non-linear perturbations and instabilities leading to local, small-scale diffusion of the magnetic fields. III) Self-gravity overcomes and the smaller clouds seed the cores of the low-mass stars.

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The Spectral Energy Distribution of the Earliest Phases of Massive Star Formation

Proceedings of the International Astronomical Union ◽

10.1017/s1743921315009102 ◽

2015 ◽

Vol 12 (S316) ◽

pp. 151-152

Author(s):

Randolf Klein ◽

Jennifer Cooper ◽

Leslie Looney ◽

Thomas Henning ◽

Sukanya Chakrabarti ◽

...

Keyword(s):

Star Formation ◽

Energy Distribution ◽

Massive Star ◽

Spectral Energy Distribution ◽

Spectral Energy ◽

Status Report ◽

Massive Star Formation ◽

Data Set ◽

Good Spatial Resolution ◽

Early Phases

AbstractWe have selected cold and massive (M > 100M⊙) cores as candidates for early phases of star formation from millimeter continuum surveys without associations at short wavelengths. We compared the millimeter continuum peak positions with IR and radio catalogs and excluded cores that had sources associated with the cores’ peaks. We compiled a list of 173 cores in over 117 regions that are candidates for very early phases of Massive Star Formation (MSF). Now with the Spitzer and Herschel archives, these cores can be characterized further. We are compiling this data set to construct the complete spectral energy distribution (SED) in the mid- and far-infrared with good spatial resolution and broad spectral coverage. This allow us to disentangle the complex regions and model the SED of the deeply embedded protostars/clusters. We present a status report of our efforts: a preview of the IR properties of all cores and their embedded source inferred from a grey body fit to the compiled SEDs.

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Chemical evolution in the early phases of massive star formation

Astronomy and Astrophysics ◽

10.1051/0004-6361/201423989 ◽

2015 ◽

Vol 579 ◽

pp. A80 ◽

Cited By ~ 16

Author(s):

T. Gerner ◽

Y. L. Shirley ◽

H. Beuther ◽

D. Semenov ◽

H. Linz ◽

...

Keyword(s):

Star Formation ◽

Chemical Evolution ◽

Massive Star ◽

Massive Star Formation ◽

Early Phases

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Magnetic fields and massive star formation

Proceedings of the International Astronomical Union ◽

10.1017/s1743921319003922 ◽

2018 ◽

Vol 14 (A30) ◽

pp. 141-141

Author(s):

Qizhou Zhang

Keyword(s):

Star Formation ◽

Magnetic Fields ◽

Massive Star ◽

Dense Core ◽

Continuum Emission ◽

Massive Star Formation ◽

Stellar Objects ◽

Star Forming ◽

Dense Cores ◽

The Mean

AbstractMassive stars ( ${\rm{M}} > \,8{M_ \odot }$ ) often form in parsec-scale molecular clumps that collapse and fragment, leading to the birth of a cluster of stellar objects. The role of magnetic fields during the formation of massive dense cores is still not clear. The steady improvement in sensitivity of (sub)millimeter interferometers over the past decade enabled observations of dust polarization of large samples of massive star formation regions. We carried out a polarimetric survey with the Submillimeter Array of 14 massive star forming clumps in continuum emission at a wavelength of 0.89 mm. This unprecedentedly large sample of massive star forming regions observed by a submillimeter interferometer before the advent of ALMA revealed compelling evidence of strong magnetic influence on the gas dynamics from 1 pc to 0.1 pc scales. We found that the magnetic fields in dense cores tend to be either parallel or perpendicular to the mean magnetic fields in their parental molecular clumps. Furthermore, the main axis of protostellar outflows does not appear to be aligned with the mean magnetic fields in the dense core where outflows are launched. These findings suggest that from 1 pc to 0.1 pc scales, magnetic fields are dynamically important in the collapse of clumps and the formation of dense cores. From the dense core scale to the accretion disk scale of ∼102 au, however, gravity and angular momentum appear to be more dominant relative to the magnetic field.

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