The Effect of Galaxy Interactions on Molecular Gas Properties

TL;DR

Galaxy interactions significantly increase molecular gas content and star formation rates, especially in close, equal-mass pairs, but have a less pronounced effect on star formation efficiency, with effects depending on merger configuration.

Contribution

This study provides the first statistical analysis of how galaxy merger configurations influence molecular gas properties using a large, carefully-selected sample.

Findings

Molecular gas mass and star formation rate are enhanced by ~2.5 times in galaxy pairs.

Enhancements are larger in systems with smaller stellar mass ratios and closer pair separations.

Star formation efficiency is only significantly increased in close, equal-mass galaxy pairs.

Abstract

Galaxy interactions are often accompanied by an enhanced star formation rate (SFR). Since molecular gas is essential for star formation, it is vital to establish whether, and by how much, galaxy interactions affect the molecular gas properties. We investigate the effect of interactions on global molecular gas properties by studying a sample of 58 galaxies in pairs and 154 control galaxies. Molecular gas properties are determined from observations with the JCMT, PMO, CSO telescopes, and supplemented with data from the xCOLD GASS and JINGLE surveys at $^{12}$CO(1-0) and $^{12}$CO(2-1). The SFR, gas mass ($M_\mathrm{H_{2}}$), and gas fraction ($f_{gas}$) are all enhanced in galaxies in pairs by $\sim$ 2.5 times compared to the controls matched in redshift, mass, and effective radius, while the enhancement of star formation efficiency (SFE $\equiv$ SFR/$M_{H_{2}}$) is less than a factor of 2. We also find that the enhancements in SFR, $M_{H_{2}}$ and $f_{gas}$ increase with decreasing pair separation and are larger in systems with smaller stellar mass ratio. Conversely, the SFE is only enhanced in close pairs (separation $<$ 20 kpc) and equal-mass systems; therefore most galaxies in pairs lie in the same parameter space on the SFR-$M_{H_{2}}$ plane as controls. This is the first time that the dependence of molecular gas properties on merger configurations is probed statistically with a relatively large sample and with a carefully-selected control sample for individual galaxies. We conclude that galaxy interactions do modify the molecular gas properties, although the strength of the effect is merger configuration dependent.