High CO depletion in southern infrared-dark clouds

TL;DR

This study measures high CO depletion factors in infrared-dark clouds, indicating early stages of high-mass star formation with chemical conditions similar to low-mass pre-stellar cores.

Contribution

It provides new measurements of CO depletion using high-density tracers, revealing larger depletion factors than previously observed in similar environments.

Findings

Measured CO depletion factors between 5 and 78, with a mean of 32.

Detected NH3 and C18O in all targets, confirming dense, potentially star-forming conditions.

Infrared-dark clumps show high depletion, suggesting early star formation stages.

Abstract

Infrared-dark high-mass clumps are among the most promising objects to study the initial conditions of the formation process of high-mass stars and rich stellar clusters. In this work, we have observed the (3-2) rotational transition of C18O with the APEX telescope, and the (1,1) and (2,2) inversion transitions of NH3 with the Australia Telescope Compact Array in 21 infrared-dark clouds already mapped in the 1.2 mm continuum, with the aim of measuring basic chemical and physical parameters such as the CO depletion factor (fD), the gas kinetic temperature and the gas mass. In particular, the C18O (3-2) line allows us to derive fD in gas at densities higher than that traced by the (1-0) and (2-1) lines, typically used in previous works. We have detected NH3 and C18O in all targets. The clumps possess mass, H2 column and surface densities consistent with being potentially the birthplace of high-mass stars. We have measured fD in between 5 and 78, with a mean value of 32 and a median of 29. These values are, to our knowledge, larger than the typical CO depletion factors measured towards infrared-dark clouds and high-mass dense cores, and are comparable to or larger than the values measured in low-mass pre-stellar cores close to the onset of the gravitational collapse. This result suggests that the earliest phases of the high-mass star and stellar cluster formation process are characterised by fD larger than in low-mass pre-stellar cores. Thirteen out of 21 clumps are undetected in the 24 {\mu}m Spitzer images, and have slightly lower kinetic temperatures, masses and H2 column densities with respect to the eight Spitzer-bright sources. This could indicate that the Spitzer-dark clumps are either less evolved or are going to form less massive objects.