An Infrared through Radio Study of the Properties and Evolution of IRDC Clumps

TL;DR

This study investigates the physical and evolutionary properties of IRDC clumps using multi-wavelength data, revealing insights into mass tracers, molecular gas characteristics, and embedded UCHII regions, contributing to understanding IRDC evolution.

Contribution

It combines new and existing data to analyze IRDC clumps, proposing an evolutionary sequence and evaluating mass tracers and molecular properties with detailed observational evidence.

Findings

Mass tracers like 8 micron extinction and 1.1 mm BGPS are complementary except in active regions.

Virial masses are higher than dust continuum masses on ~1 pc scales.

Active clumps show brighter molecular lines and contain embedded UCHII regions.

Abstract

We examine the physical properties and evolutionary stages of a sample of 17 clumps within 8 Infrared Dark Clouds (IRDCs) by combining existing infrared, millimeter, and radio data with new Bolocam Galactic Plane Survey (BGPS) 1.1 mm data, VLA radio continuum data, and HHT dense gas (HCO+ and N2H+) spectroscopic data. We combine literature studies of star formation tracers and dust temperatures within IRDCs with our search for ultra-compact (UC) HII regions to discuss a possible evolutionary sequence for IRDC clumps. In addition, we perform an analysis of mass tracers in IRDCs and find that 8 micron extinction masses and 1.1 mm Bolocam Galactic Plane Survey (BGPS) masses are complementary mass tracers in IRDCs except for the most active clumps (notably those containing UCHII regions), for which both mass tracers suffer biases. We find that the measured virial masses in IRDC clumps are uniformly higher than the measured dust continuum masses on the scale of ~1 pc. We use 13CO, HCO+, and N2H+ to study the molecular gas properties of IRDCs and do not see any evidence of chemical differentiation between hot and cold clumps on the scale of ~1 pc. However, both HCO+ and N2H+ are brighter in active clumps, due to an increase in temperature and/or density. We report the identification of four UCHII regions embedded within IRDC clumps and find that UCHII regions are associated with bright (>1 Jy) 24 micron point sources, and that the brightest UCHII regions are associated with "diffuse red clumps" (an extended enhancement at 8 micron). The broad stages of the discussed evolutionary sequence (from a quiescent clump to an embedded HII region) are supported by literature dust temperature estimates; however, no sequential nature can be inferred between the individual star formation tracers.