The Impact of Molecular Gas on Mass Models of Nearby Galaxies

TL;DR

This study investigates how molecular gas, traced by CO, influences mass models of nearby galaxies, comparing different conversion factors and analyzing their impact on dark matter halo profiles.

Contribution

It provides a comprehensive analysis combining CO and HI kinematics with different $ m eta_{CO}$ values to assess molecular gas effects on galaxy mass models.

Findings

Good agreement between CO and HI kinematics in most galaxies.

Molecular gas contribution varies significantly with $ m eta_{CO}$.

Different $ m eta_{CO}$ values affect dark matter halo shape in galaxy centers.

Abstract

We present CO velocity fields and rotation curves for a sample of nearby galaxies, based on data from the HERACLES survey. We combine our data with literature THINGS, SINGS and KINGFISH results to provide a comprehensive sample of mass models of disk galaxies inclusive of molecular gas. We compare the kinematics of the molecular (CO from HERACLES) and atomic (${\rm H{\scriptstyle I}}$ from THINGS) gas distributions to determine the extent to which CO may be used to probe the dynamics in the inner part of galaxies. In general, we find good agreement between the CO and ${\rm H{\scriptstyle I}}$ kinematics with small differences in the inner part of some galaxies. We add the contribution of the molecular gas to the mass models in our galaxies by using two different conversion factors $\mathrm{\alpha_{CO}}$ to convert CO luminosity to molecular gas mass surface density - the constant Milky Way value and the radially varying profiles determined in recent work based on THINGS, HERACLES and KINGFISH data. We study the relative effect that the addition of the molecular gas has upon the halo rotation curves for Navarro-Frenk-White (NFW) and the observationally motivated pseudo-isothermal halos. The contribution of the molecular gas varies for galaxies in our sample - for those galaxies where there is a substantial molecular gas content, using different values of $\mathrm{\alpha_{CO}}$ can result in significant differences to the relative contribution of the molecular gas and, hence, the shape of the dark matter halo rotation curves in the central regions of galaxies.