WISDOM Project -- XVII. Beam-by-beam Properties of the Molecular Gas in Early-type Galaxies

TL;DR

This study investigates the properties of molecular gas in seven early-type galaxies at high spatial resolution, revealing that the gas is generally unbound, highly compressed, and influenced by large-scale galactic dynamics, contrasting with star-forming spiral galaxies.

Contribution

First detailed high-resolution analysis of molecular gas properties in early-type galaxies, highlighting differences from spiral galaxies and the impact of large-scale dynamics.

Findings

Molecular gas has a wide range of surface densities and higher velocity dispersions than in spiral galaxies.

Gas is generally super-virial and not in dynamic equilibrium, indicating strong compression.

Large-scale galactic dynamics significantly influence the molecular gas state and star formation regulation.

Abstract

We present a study of the molecular gas of seven early-type galaxies with high angular resolution data obtained as part of the mm-Wave Interferometric Survey of Dark Object Masses (WISDOM) project with the Atacama Large Millimeter/submillimeter Array. Using a fixed spatial scale approach, we study the mass surface density ($\Sigma$) and velocity dispersion ($\sigma$) of the molecular gas on spatial scales ranging from $60$ to $120$pc. Given the spatial resolution of our data ($20$ - $70$pc), we characterise these properties across many thousands of individual sight lines ($\approx50,000$ at our highest physical resolution). The molecular gas along these sight lines has a large range ($\approx2$dex) of mass surface densities and velocity dispersions $\approx40\%$ higher than those of star-forming spiral galaxies. It has virial parameters $\alpha_\mathrm{vir}$ that depend weakly on the physical scale observed, likely due to beam smearing of the bulk galactic rotation, and is generally super-virial. Comparing the internal turbulent pressure ($P_\mathrm{turb}$) to the pressure required for dynamic equilibrium ($P_\mathrm{DE}$), the ratio $P_\mathrm{turb}$/$P_\mathrm{DE}$ is significantly less than unity in all galaxies, indicating that the gas is not in dynamic equilibrium and is strongly compressed, in apparent contradiction to the virial parameters. This may be due to our neglect of shear and tidal forces, and/or the combination of three-dimensional and vertical diagnostics. Both $\alpha_\mathrm{vir}$ and $P_\mathrm{turb}$ anti-correlate with the global star-formation rate of our galaxies. We therefore conclude that the molecular gas in early-type galaxies is likely unbound, and that large-scale dynamics likely plays a critical role in its regulation. This contrasts to the giant molecular clouds in the discs of late-type galaxies, that are much closer to dynamical equilibrium.