Molecular gas budget of strongly magnified low-mass star-forming galaxies at cosmic noon

TL;DR

This study investigates the molecular gas content of strongly magnified low-mass star-forming galaxies at cosmic noon using CO and dust emission, revealing a significant atomic gas reservoir and a molecular gas deficit in these galaxies.

Contribution

First direct measurements of molecular gas in low-mass, high-redshift galaxies using lensing and multi-tracer methods, highlighting a potential atomic gas dominance.

Findings

Most galaxies have lower molecular gas fractions than expected.

Detected CO in 3 out of 12 galaxies, dust in 3 galaxies.

Atomic gas may constitute about 91% of total gas in these systems.

Abstract

This study aims to investigate the molecular gas content of strongly magnified low-mass star-forming galaxies around the cosmic noon period ($z\sim2$) through observations of CO emission lines and dust continuum emission, both of which serve as tracers for molecular gas. We observed twelve strongly lensed galaxies with the Atacama Compact Array to detect CO mid-j rotational transitions and dust continuum. Thanks to the strong lensing, we were able to probe the low-mass regime, previously understudied. With a compiled set of observations, we recalibrate empirical relations between star formation rate density and the CO line ratios. Using SED fitting, we derived galaxy properties and performed galaxy stacking to combine the faint signals. In all cases, molecular gas masses were estimated using both tracers. We detected CO emission in three out of 12 galaxies and dust continuum emission in three of them. The obtained molecular gas masses indicate that most of these galaxies ($\rm{M}_* < 10^{10.7}$ $\rm{M}_\odot$) have lower molecular gas fractions and shorter depletion times compared to the expectations from established scaling relations at these redshifts. Several possible explanations for this gas deficit were explored, including uncertainties in mass estimates, effects of low metallicity environments, larger atomic gas reservoirs in low-mass systems, and the possibility that these represent low-mass analogs of "main sequence starburst" galaxies, which are undergoing sustained star formation due to gas compaction despite low overall gas fractions. We conclude that there is a molecular gas deficit at these mass and metallicity regimes. Our results suggest that this deficit is likely due to a significant amount of atomic gas, which our stacking indicates is about 91% of the total gas. However, this estimation might be an upper limit in the case of our galaxies containing CO-dark gas.