Bibcode
Birkin, Jack E.; Weiss, Axel; Wardlow, J. L.; Smail, Ian; Swinbank, A. M.; Dudzevičiūtė, U.; An, Fang Xia; Ao, Y.; Chapman, S. C.; Chen, Chian-Chou; da Cunha, E.; Dannerbauer, H.; Gullberg, B.; Hodge, J. A.; Ikarashi, S.; Ivison, R. J.; Matsuda, Y.; Stach, S. M.; Walter, F.; Wang, W. -H.; van der Werf, P.
Bibliographical reference
Monthly Notices of the Royal Astronomical Society
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3
2021
Citations
67
Refereed citations
56
Description
We have used ALMA and NOEMA to study the molecular gas reservoirs in 61 ALMA-identified submillimetre galaxies (SMGs) in the COSMOS, UDS, and ECDFS fields. We detect 12CO ( $J_{\rm up} =$ 2-5) emission lines in 50 sources, and [C I](3P1 - 3P0) emission in eight, at $z =$ 1.2-4.8 and with a median redshift of 2.9 ± 0.2. By supplementing our data with literature sources, we construct a statistical CO spectral line energy distribution and find that the 12CO line luminosities in SMGs peak at Jup ∼ 6, consistent with similar studies. We also test the correlations of the CO, [C I], and dust as tracers of the gas mass, finding the three to correlate well, although the CO and dust mass as estimated from the 3-mm continuum are preferable. We estimate that SMGs lie mostly on or just above the star-forming main sequence, with a median gas depletion timescale, tdep = Mgas/SFR, of 210 ± 40 Myr for our sample. Additionally, tdep declines with redshift across z ∼ 1-5, while the molecular gas fraction, μgas = Mgas/M*, increases across the same redshift range. Finally, we demonstrate that the distribution of total baryonic mass and dynamical line width, Mbaryon-σ, for our SMGs is consistent with that followed by early-type galaxies in the Coma cluster, providing strong support to the suggestion that SMGs are progenitors of massive local spheroidal galaxies. On the basis of this, we suggest that the SMG populations above and below an 870-μm flux limit of S870 ∼ 5 mJy may correspond to the division between slow and fast rotators seen in local early-type galaxies.
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Two of the most fundamental questions in astrophysics are the conversion of molecular gas into stars and how this physical process is a function of environments on all scales, ranging from planetary systems, stellar clusters, galaxies to galaxy clusters. The main goal of this internal project is to get insight into the formation and evolution of
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