Magnetically Dominated Parallel Interstellar Filaments at the Infrared Dark Cloud G14.225-0.506

The G14.225-0.506 infrared dark cloud (IRDC G14.2) displays a remarkable complex of parallel dense molecular filaments projected on the plane of the sky. Previous dust emission and molecular-line studies have speculated whether magnetic fields could have played an important role in the formation of...

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Bibliographic Details
Published inarXiv.org
Main Authors Santos, Fabio P, Busquet, Gemma, Franco, Gabriel A P, Girart, Josep M, Zhang, Qizhou
Format Paper Journal Article
LanguageEnglish
Published Ithaca Cornell University Library, arXiv.org 27.09.2016
Subjects
Computer simulation
Elongated structure
Emission analysis
Filaments
Gravitation
Gravitational collapse
Interstellar
Magnetic fields
Magnetism
Molecular clouds
Morphology
Near infrared radiation
Physics - Astrophysics of Galaxies
Polarimetry
Stellar magnetic fields
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Summary:The G14.225-0.506 infrared dark cloud (IRDC G14.2) displays a remarkable complex of parallel dense molecular filaments projected on the plane of the sky. Previous dust emission and molecular-line studies have speculated whether magnetic fields could have played an important role in the formation of such long-shaped structures, which are hosts to numerous young stellar sources. In this work we have conducted a vast polarimetric survey at optical and near-infrared wavelengths in order to study the morphology of magnetic field lines in IRDC G14.2 through the observation of background stars. The orientation of interstellar polarization, which traces magnetic field lines, is perpendicular to most of the filamentary features within the cloud. Additionally, the larger-scale molecular cloud as a whole exhibits an elongated shape also perpendicular to magnetic fields. Estimates of magnetic field strengths indicate values in the range \(320 - 550\,\mu\)G, which allows sub-alfvénic conditions, but does not prevent the gravitational collapse of hub-filament structures, which in general are close to the critical state. These characteristics suggest that magnetic fields played the main role in regulating the collapse from large to small scales, leading to the formation of series of parallel elongated structures. The morphology is also consistent with numerical simulations that show how gravitational instabilities develop under strong magnetic fields. Finally, the results corroborate the hypothesis that a strong support from internal magnetic fields might explain why the cloud seems to be contracting on a time scale 2-3 times larger than what is expected from a free-fall collapse.
ISSN:2331-8422
DOI:10.48550/arxiv.1609.08052