Molecular gas in AzTEC/C159: a star-forming disk galaxy 1.3Gyr after the Big Bang

Abstract

We studied the molecular gas properties of AzTEC/C159, a star-forming disk galaxy at z=4.567. We secured 12CO molecular line detections for the J=21 and J=54 transitions using the Karl G. Jansky VLA and the NOEMA interferometer. The broad (FWHM750\, km\,s-1) and tentative double-peaked profiles of both 12CO lines are consistent with an extended molecular gas reservoir, which is distributed in a rotating disk as previously revealed from [CII] 158μm line observations. Based on the 12CO(21) emission line we derived L'CO=(3.40.6)×1010 \,K\,km\,s-1 \,pc2, that yields a molecular gas mass of M H2 (α CO/4.3)=(1.50.3)× 1011 M and unveils a gas-rich system with μ gas(α CO/4.3) M H2/M=3.30.7. The extreme star formation efficiency (SFE) of AzTEC/C159, parametrized by the ratio LIR/L'CO=(21680)\, L \,(K\,km\,s-1 \,pc2)-1, is comparable to merger-driven starbursts such as local ultra-luminous infrared galaxies (ULIRGs) and SMGs. Likewise, the 12CO(54)/CO(21) line brightness temperature ratio of r52= 0.55 0.15 is consistent with high excitation conditions, similar to that observed in SMGs. We constrained the value for the L'CO- H2 mass conversion factor in AzTEC/C159, i.e. αCO=3.9+2.7-1.3 \,M \,K-1 \,km-1 \,s\,pc-2, that is consistent with a self-gravitating molecular gas distribution as observed in local star-forming disk galaxies. Cold gas streams from cosmological filaments might be fueling a gravitationally unstable gas-rich disk in AzTEC/C159, which breaks into giant clumps forming stars as efficiently as in merger-driven systems and generate high gas excitation.