Understanding star formation in molecular clouds II. Signatures of   gravitational collapse of IRDCs

N. Schneider (1); T. Csengeri (2); R.S. Klessen (3); P. Tremblin (4),; V. Ossenkopf (5); N. Peretto (6); R. Simon (5); S. Bontemps (1); C. Federrath; (7) ((1) Universite Bordeaux; LAB/OASU; France; (2) MPIfR; Bonn; Germany; (3); Zentrum fuer Astronomie der Universitaet Heidelberg; Inst. fuer Theor.; Astrophysik; Heidelberg; Germany; (4) Astrophysics Group; University of; Exeter; UK; (5) I. Physik. Institut; Universitaet zu Koeln; Germany; (6); School of Physics; Astronomy; Cardiff University; UK; (7) Research School; of Astronomy & Astrophysics; Australian National University; Canberra,; Australia)

arXiv:1406.3134·astro-ph.GA·May 27, 2015·41 cites

Understanding star formation in molecular clouds II. Signatures of gravitational collapse of IRDCs

N. Schneider (1), T. Csengeri (2), R.S. Klessen (3), P. Tremblin (4),, V. Ossenkopf (5), N. Peretto (6), R. Simon (5), S. Bontemps (1), C. Federrath, (7) ((1) Universite Bordeaux, LAB/OASU, France, (2) MPIfR, Bonn, Germany, (3)

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TL;DR

This study analyzes Herschel dust continuum data and molecular line observations of infrared dark clouds to identify signatures of gravitational collapse, revealing power-law column density PDFs and infall motions indicative of star formation processes.

Contribution

It demonstrates that IRDCs exhibit power-law column density PDFs and infall signatures, linking gravitational collapse to their dense structure and star-forming potential, contrasting previous log-normal findings.

Findings

01

IRDCs show power-law PDFs over high column densities.

02

Infall signatures support gravitational collapse in IRDCs.

03

IRDCs are the densest regions in GMCs, potential sites of massive star formation.

Abstract

We analyse column density and temperature maps derived from Herschel dust continuum observations of a sample of massive infrared dark clouds (G11.11-0.12, G18.82-0.28, G28.37+0.07, G28.53-0.25). We disentangle the velocity structure of the clouds using 13CO 1-0 and 12CO 3-2 data, showing that these IRDCs are the densest regions in massive giant molecular clouds and not isolated features. The probability distribution function (PDF) of column densities for all clouds have a power-law distribution over all (high) column densities, regardless of the evolutionary stage of the cloud: G11.11-0.12, G18.82-0.28, and G28.37+0.07 contain (proto)-stars, while G28.53-0.25 shows no signs of star formation. This is in contrast to the purely log-normal PDFs reported for near/mid-IR extinction maps. We only find a log-normal distribution for lower column densities, if we perform PDFs of the column…

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Taxonomy

TopicsAstrophysics and Star Formation Studies · Stellar, planetary, and galactic studies · Molecular Spectroscopy and Structure