Direct detection of cool molecular gas in a star-forming galaxy at z=7.31

Abstract

We investigate the molecular gas content and interstellar medium (ISM) conditions of REBELS-25, a massive, star-forming galaxy at z=7.31. Deep VLA Q-band and ALMA Band 3 observations reveal CO(3-2) and CO(7-6) emission (both at 3.5σ), and provide an upper limit on [C I](2-1). From the CMB-corrected CO(3-2) flux-representing the highest-redshift detection of a low-J CO transition to date-we derive a molecular gas mass of M mol=(1.00.4)×1011\,(α CO/(3\,M(K\,\,pc2)-1))\,M, directly confirming the presence of a very massive gas reservoir only 700\,Myr after the Big Bang. This implies an extreme gas fraction of f gas0.95, a gas-to-dust ratio of δ GDR6×102, and a depletion timescale of τ dep1.2\,Gyr, broadly consistent with extrapolated scaling relations for main-sequence galaxies at lower redshift. Using the radiative transfer code TUNER, we self-consistently model CO and dust continuum emission in the context of the significant CMB background, constraining ISM properties and recovering M mol= (1.8+1.0-0.9)×1011\,M, independent of assumptions about r31 and α CO. We further discuss the use of alternative molecular gas tracers at early epochs. Combining CO and [C II] measurements, we infer an empirical [C II]-to-H2 conversion factor of α [C II]=(6025)\,M/L, suggesting [C II] remains a viable molecular gas tracer in the Epoch of Reionization. These results demonstrate the detectability of low-J CO emission even at z>7, paving the way for next-generation facilities, and provide critical insights into the rapid mass assembly of galaxies during the first billion years of cosmic history.