Far-Infrared Dust Temperatures and Column Densities of the MALT90 Molecular Clump Sample

TL;DR

This study derives dust temperatures and column densities for approximately 3000 high-mass molecular clumps using far-infrared data, revealing temperature and density profiles across different evolutionary stages.

Contribution

It provides a large-scale analysis of dust properties in high-mass star-forming regions, highlighting differences across evolutionary stages with detailed temperature and density profiles.

Findings

Quiescent clumps have lower temperatures (~16.8 K) and shallower density profiles.

Protostellar clumps show higher median densities (~0.20 g/cm²) and steeper profiles.

Dust temperature gradients indicate internal heating in more evolved clumps.

Abstract

We present dust column densities and dust temperatures for $\sim3000$ young high-mass molecular clumps from the Millimetre Astronomy Legacy Team 90 GHz (MALT90) survey, derived from adjusting single temperature dust emission models to the far-infrared intensity maps measured between 160 and 870 \micron\ from the Herschel/Hi-Gal and APEX/ATLASGAL surveys. We discuss the methodology employed in analyzing the data, calculating physical parameters, and estimating their uncertainties. The population average dust temperature of the clumps are: $16.8\pm0.2$ K for the clumps that do not exhibit mid-infrared signatures of star formation (Quiescent clumps), $18.6\pm0.2$ K for the clumps that display mid-infrared signatures of ongoing star formation but have not yet developed an HII region (Protostellar clumps), and $23.7\pm0.2$ and $28.1\pm0.3$ K for clumps associated with HII and photo-dissociation regions, respectively. These four groups exhibit large overlaps in their temperature distributions, with dispersions ranging between 4 and 6 K. The median of the peak column densities of the Protostellar clump population is $0.20\pm0.02$ gr cm$^{-2}$, which is about 50% higher compared to the median of the peak column densities associated with clumps in the other evolutionary stages. We compare the dust temperatures and column densities measured toward the center of the clumps with the mean values of each clump. We find that in the Quiescent clumps the dust temperature increases toward the outer regions and that they are associated with the shallowest column density profiles. In contrast, molecular clumps in the Protostellar or HII region phase have dust temperature gradients more consistent with internal heating and are associated with steeper column density profiles compared with the Quiescent clumps.