The Bolocam Galactic Plane Survey. VII. Characterizing the Properties of Massive Star-Forming Regions

TL;DR

This study uses GBT observations of NH3 lines to analyze 631 BGPS sources, revealing their physical properties, Galactic distribution, and star formation activity, with implications for understanding dense gas and star formation efficiency across the Milky Way.

Contribution

It provides the first comprehensive NH3-based characterization of BGPS sources, including distance resolution, physical properties, and star formation potential across the Galactic disk.

Findings

72% of targets detected in NH3, confirming dense gas presence

Sources peak between 4-5 kpc Galactocentric radius

67% show signs of star formation activity

Abstract

We present the results of a GBT survey of NH3(1,1), (2,2), (3,3) lines towards 631 Bolocam Galactic Plane Survey (BGPS) sources at a range of Galactic longitudes in the inner Galaxy. We have detected the NH3(1,1) line towards 72% of our targets (456), demonstrating that the high column density features identified in the BGPS and other continuum surveys accurately predict the presence of dense gas. We have determined kinematic distances and resolved the distance ambiguity for all BGPS sources detected in NH3. The BGPS sources trace the locations of the Scutum and Sagittarius spiral arms, with the number of sources peaking between Galactocentric radii of 4-5 kpc. We measure the physical properties of each source and find that depending on the distance, BGPS sources are primarily clumps, with some cores and clouds. We have examined the physical properties as a function of Galactocentric distance, and find a mean gas kinetic temperature of 15.6 K, and that the NH3 column density and abundance decrease by nearly an order of magnitude between Galactocentric radii of 3 - 11 kpc. Comparing sources at similar distances demonstrates that the physical properties are indistinguishable, which suggests a similarity in clump structure across the Galactic disk. We have also compared the BGPS sources to criteria for efficient star formation presented independently by Heiderman et al. and Lada et al., and massive star formation presented by Kauffmann et al. 48% of our sample should be forming stars (including massive stars) with high efficiency, and 87% contain subregions that should be efficiently forming stars. Indeed, we find that 67% of the sample exhibit signs of star formation activity based on an association with a mid-IR source.