13CO 1-0 imaging of the Medusa merger, NGC4194

TL;DR

This study uses CO and 13CO 1-0 line imaging to analyze molecular gas properties in the Medusa merger, revealing a central gradient in line ratios linked to starburst activity and diffuse gas, with implications for understanding galaxy evolution.

Contribution

First detailed interferometric imaging of CO and 13CO in the Medusa merger, highlighting the central gas properties and gradients related to starburst activity.

Findings

Line ratio increases from 7-10 in outer regions to >40 in the center.

Central gradient mainly caused by diffuse gas in the dust lane.

Medusa's star formation phase resembles high-redshift galaxy traits.

Abstract

Studying molecular gas properties in merging galaxies gives important clues to the onset and evolution of interaction-triggered starbursts. The CO/13CO 1-0 line intensity ratio can be used as a tracer of how dynamics and star formation processes impact the gas properties. The Medusa (NGC~4194) merger is particularly interesting to study since its LFIR/LCO ratio rivals that of ultraluminous galaxies (ULIRGs), despite the comparatively modest luminosity, indicating an exceptionally high star formation efficiency (SFE) in the Medusa merger. Interferometric OVRO observations of CO and 13CO 1-0 in the Medusa show the CO/13CO intensity ratio increases from normal, quiescent values (7-10) in the outer parts (r>2 kpc) of the galaxy to high (16 to >40) values in the central (r<1 kpc) starburst region. In the centre there is an east-west gradient where the line ratio changes by more than a factor of three over 5" (945 pc). The integrated 13CO emission peaks in the north-western starburst region while the central CO emission is strongly associated with the prominent crossing dust-lane. We discuss the central east-west gradient in the context of gas properties in the starburst and the central dust lane. We suggest that the central gradient is mainly caused by diffuse gas in the dust lane. In this scenario, the actual molecular mass distribution is better traced by the 13CO 1-0 emission than the CO. The possibilities of temperature and abundance gradients are also discussed. We compare the central gas properties of the Medusa to those of other minor mergers and suggest that the extreme and transient phase of the Medusa star formation activity has similar traits to those of high-redshift galaxies.