The Dense Gas Fraction in Galactic Center Clouds

TL;DR

This study analyzes gas densities in the Galactic Center clouds using HC3N molecular transitions, revealing multiple excitation regimes and a lower dense gas fraction than star-forming regions, supporting models of gas dynamics and star formation thresholds.

Contribution

It provides the first detailed density analysis of multiple Galactic Center clouds using HC3N, identifying distinct excitation regimes and quantifying the dense gas fraction.

Findings

Low-excitation component density < 10^4 cm^-3

High-excitation component density between 10^5 and 10^6 cm^-3

Dense gas fraction ~15% in all three clouds

Abstract

We present an analysis of gas densities in the central R=300 parsecs of the Milky Way, focusing on three clouds: GCM-0.02-0.07 (the 50 km/s cloud), GCM-0.13-0.08 (the 20 km/s cloud), and GCM0.25+0.01 (the "Brick"). Densities are determined using observations of the J=(3-2), (4-3), (5-4), (10-9), (18-17), (19-18), (21-20), and (24-23) transitions of the molecule HC3N. We find evidence of at least two excitation regimes for HC3N and constrain the low-excitation component to have a density less than 10^4 cm^-3 and the high-excitation component to have a density between 10^5 and 10^6 cm^-3. This is much less than densities of 10^7 cm^-3 that are found in Sgr B2, the most actively star-forming cloud in the Galactic center. This is consistent with the requirement of a higher density threshold for star formation in the Galactic center than is typical in the Galactic disk. We are also able to constrain the column density of each component in order to determine the mass fraction of 'dense' (n>10^5 cm^-3) gas for these clouds. We find that this is ~15% for all three clouds. Applying the results of our models to ratios of the (10-9) and (3-2) line across the entire central R=300 pc, we find that the fraction of gas with n>10^4 cm^-3 increases inward of a radius of ~140 pc, consistent with the predictions of recent models for the gas dynamics in this region. Our observations show that HC3N is an excellent molecule for probing the density structure of clouds in the Galactic center.