The Bluedisk Survey: molecular gas distribution and scaling relations in the context of galaxy evolution

TL;DR

This study examines how gas accretion influences molecular gas distribution and star formation in disc galaxies, revealing that HI-rich galaxies have similar molecular gas masses but distinct outer disc properties compared to control galaxies.

Contribution

It provides new insights into the effects of ongoing gas accretion on molecular gas distribution and star formation efficiency in disc galaxies.

Findings

HI-rich galaxies have similar H2 masses as control galaxies.

Outer disc regions in HI-rich galaxies show steeper gradients and smaller CO extents.

Gas accretion is likely to fuel star formation over at least 5 Gyr.

Abstract

One of the key goals of the Bluedisk survey is to characterize the impact of gas accretion in disc galaxies in the context of galaxy evolution. It contains 50 disc galaxies in the stellar mass range 10^10-10^11 Msun, of which half are bluer and more HI-rich galaxies than their HI-normal (control) counterparts. In this paper, we investigate how ongoing disc growth affects the molecular gas distribution and the star-formation efficiency in these galaxies. We present 12CO observations from the IRAM 30-m telescope in 26 galaxies of the Bluedisk survey. We compare the amount and spatial distribution of the molecular gas to key quantities such as atomic gas, stellar mass and surface density, star-formation rate and metallicity. We analyse the star-formation rate per unit gas (SFR/HI and SFR/H2) and relate all those parameters to general galaxy properties (HI-rich/control disc, morphology, etc.). We find that the HI-rich galaxies have similar H2 masses as the control galaxies. In their centres, HI-rich galaxies have lower H2/HI ratios and marginally shorter molecular gas depletion times. However, the main differences between the two samples occur in the outer parts of the discs, with the HI-rich galaxies having slightly smaller CO discs (relative to the optical radius R25) and steeper CO and metallicity gradients than the control galaxies. The ongoing accretion of HI at large radii has thus not led to an appreciable growth of the CO discs in our sample. Based on depletion times, we estimate that this gas will contribute to star formation on time-scales of at least 5 Gyr.