Physical Properties and Galactic Distribution of Molecular Clouds identified in the Galactic Ring Survey

TL;DR

This study analyzes the physical properties and distribution of 580 molecular clouds in the Milky Way, revealing their fractal nature, spatial variations, and potential links to spiral arm star formation.

Contribution

It provides a detailed analysis of molecular cloud properties, establishes a power-law relation between their size and mass, and maps their distribution across the Galaxy.

Findings

Power-law relation between cloud radius and mass with exponent ~2.36.

Galactic surface density peaks between 4-5 kpc from the center.

Temperature decline suggests decreasing star formation rate outward.

Abstract

We derive the physical properties of 580 molecular clouds based on their 12CO and 13CO line emission detected in the University of Massachusetts-Stony Brook (UMSB) and Galactic Ring surveys. We provide a range of values of the physical properties of molecular clouds, and find a power-law correlation between their radii and masses, suggesting that the fractal dimension of the ISM is around 2.36. This relation, M = (228 +/- 18) R^{2.36+/-0.04}, allows us to derive masses for an additional 170 GRS molecular clouds not covered by the UMSB survey. We derive the Galactic surface mass density of molecular gas and examine its spatial variations throughout the Galaxy. We find that the azimuthally averaged Galactic surface density of molecular gas peaks between Galactocentric radii of 4 and 5 kpc. Although the Perseus arm is not detected in molecular gas, the Galactic surface density of molecular gas is enhanced along the positions of the Scutum-Crux and Sagittarius arms. This may indicate that molecular clouds form in spiral arms and are disrupted in the inter-arm space. Last, we find that the CO excitation temperature of molecular clouds decreases away from the Galactic center, suggesting a possible decline in the star formation rate with Galactocentric radius. There is a marginally significant enhancement in the CO excitation temperature of molecular clouds at a Galactocentric radius of about 6 kpc, which in the longitude range of the GRS corresponds to the Sagittarius arm. This temperature increase could be associated with massive star formation in the Sagittarius spiral arm.