Dense molecular gas properties on 100 pc scales across the disc of NGC 3627

TL;DR

This study uses high-resolution millimeter observations to analyze dense molecular gas properties across the galaxy NGC 3627, revealing environmental influences on gas density, star formation efficiency, and complex gas dynamics within the galaxy.

Contribution

First high-resolution map of dense gas tracers across a nearby spiral galaxy's disc, showing environmental dependence of dense gas properties and star formation.

Findings

Dense gas ratios vary with galactic environment, not star formation.

Central dense gas is less efficient at forming stars despite higher density.

Complex gas dynamics at bar ends are linked to star formation activity.

Abstract

It is still poorly constrained how the densest phase of the interstellar medium varies across galactic environment. A large observing time is required to recover significant emission from dense molecular gas at high spatial resolution, and to cover a large dynamic range of extragalactic disc environments. We present new NOrthern Extended Millimeter Array (NOEMA) observations of a range of high critical density molecular tracers (HCN, HNC, HCO+) and CO isotopologues (13CO, C18O) towards the nearby (11.3 Mpc), strongly barred galaxy NGC 3627. These observations represent the current highest angular resolution (1.85"; 100 pc) map of dense gas tracers across a disc of a nearby spiral galaxy, which we use here to assess the properties of the dense molecular gas, and their variation as a function of galactocentric radius, molecular gas, and star formation. We find that the HCN(1-0)/CO(2-1) integrated intensity ratio does not correlate with the amount of recent star formation. Instead, the HCN(1-0)/CO(2-1) ratio depends on the galactic environment, with differences between the galaxy centre, bar, and bar end regions. The dense gas in the central 600 pc appears to produce stars less efficiently despite containing a higher fraction of dense molecular gas than the bar ends where the star formation is enhanced. In assessing the dynamics of the dense gas, we find the HCN(1-0) and HCO+(1-0) emission lines showing multiple components towards regions in the bar ends that correspond to previously identified features in CO emission. These features are co-spatial with peaks of Halpha emission, which highlights that the complex dynamics of this bar end region could be linked to local enhancements in the star formation.