Molecular Gas and Star Formation in Nearby Disk Galaxies

Abstract

We compare molecular gas traced by 12CO(2-1) maps from the HERACLES survey, with tracers of the recent star formation rate (SFR) across 30 nearby disk galaxies. We demonstrate a first-order linear correspondence between Sigmol and SigSFR but also find important second-order systematic variations in the apparent molecular gas depletion time, tdepmol = Sigmol / SigSFR. At our 1 kpc common resolution, CO correlates closely with many tracers of the recent SFR. Weighting each line of sight equally and using a fixed, Milky Way alphaCO, our data yield a molecular gas depletion time, tdepmol=Sigmol/SigSFR ~ 2.2 Gyr with 0.3 dex scatter, in good agreement with literature data. We apply a forward-modeling approach to constrain the power-law index, N, that relates the SFR surface density and the molecular gas surface density and find N=1+/-0.15 for our full data set with some variation from galaxy to galaxy. However, we caution that a power law treatment oversimplifies the topic given that we observe correlations between tdepmol and other local and global quantities. The strongest of these are a decreased tdepmol in low-mass, low-metallicity galaxies and a correlation of the kpc-scale tdepmol with dust-to-gas ratio, D/G. These correlations can be explained by a CO-to-H2 conversion factor that depends on D/G in the theoretically expected way. This is not a unique interpretation, but external evidence of conversion factor variations makes it a conservative one. After applying a D/G-dependent alphaCO, some weak correlations between tdepmol and local conditions persist. In particular, we observe lower tdepmol and enhanced CO excitation associated with some nuclear gas concentrations. These appear to reflect real enhancements in the SFR/H2 and tdep appears multivalued at fixed Sigmol, supporting the the idea of "disk" and "starburst" modes driven by environmental factors.