An ALMA survey of the SCUBA-2 CLS UDS field: physical properties of 707 sub-millimetre galaxies

Dudzevičiūtė, U.; Smail, Ian; Swinbank, A. M.; Stach, S. M.; Almaini, O.; Cunha, Elisabete da; An, Fang Xia; Arumugam, V.; Birkin, Jack E.; Blain, A. W.; Chapman, Scott; Chen, Chian-Chou; Conselice, Christopher J.; Coppin, K. E. K.; Dunlop, James; Farrah, D.; Geach, J. E.; Gullberg, B.; Hartley, W. G.; Hodge, J. A.; Ivison, R. J.; Maltby, David T.; Scott, Douglas; Simpson, Chris; Simpson, J. M.; Thomson, A. P.; Walter, Fabian; Wardlow, J. L.; Weiß, A.; Werf, P. P. van der

doi:10.1093/mnras/staa769

Cited by 236 publications

(623 citation statements)

References 166 publications

(297 reference statements)

Supporting

Mentioning

533

Contrasting

Order By: Relevance

“…Interestingly there are reported DSFGs at > 4¯5 with increasing flux densities with increasing wavelength resembling jet emission (Ivison et al 2016;Riechers et al 2017) . However, given the likely rarity of such sources (the redshift distribution of DSFGs spans = 1-3, Chapman et al 2005;Dudzevičiūtė et al 2020, observed at similar wavelengths) we consider this possibility fairly unlikely. Now considering the geometry, we identify seven fields with pairs of submillimetre detections that are diametrically opposite each other along a line which passes trough the calibrator.…”

Section: Identifying Jet Emission From Calibratorsmentioning

confidence: 95%

“…These galaxies are radio bright because the line of sight coincides with the direction of the jet and not because they are particularly radioluminous or massive (De Breuck et al 2002;Seymour et al 2007). However, most DSFGs are at z 1 (Dudzevičiūtė et al 2020) while the calibrators are mostly below z ∼ 1 with a tail to z ∼ 3 (see Table 1). Therefore, it is less likely that the calibrator and the DSFGs are physically associated.…”

Section: Clustering Of Sourcesmentioning

confidence: 99%

See 1 more Smart Citation

ALMACAL VII: first interferometric number counts at 650 μm

Klitsch

Smail

Péroux

et al. 2020

Monthly Notices of the Royal Astronomical Society

Self Cite

View full text Add to dashboard Cite

Measurements of the cosmic far-infrared background (CIB) indicate that emission from many extragalactic phenomena, including star formation and black hole accretion, in the Universe can be obscured by dust. Resolving the CIB to study the population of galaxies in which this activity takes place is a major goal of submillimetre astronomy. Here, we present interferometric 650 μm submillimetre number counts. Using the Band 8 data from the ALMACAL survey, we have analysed 81 ALMA calibrator fields together covering a total area of 5.5 arcmin2. The typical central rms in these fields is ∼100 μJy beam−1 with the deepest maps reaching σ = 47 μJy beam−1 at sub-arcsec resolution. Multiwavelength coverage from ALMACAL allows us to exclude contamination from jets associated with the calibrators. However, residual contamination by jets and lensing remain a possibility. Using a signal-to-noise threshold of 4.5σ, we find 21 dusty, star-forming galaxies with 650 μm flux densities of ≥0.7mJy. At the detection limit we resolve ≃100 per cent of the CIB at 650 μm, a significant improvement compared to low-resolution studies at similar wavelength. We have therefore identified all the sources contributing to the EBL at 650 μm and predict that the contribution from objects with flux 0.7 mJy will be small.

show abstract

Section: Identifying Jet Emission From Calibratorsmentioning

confidence: 95%

Section: Clustering Of Sourcesmentioning

confidence: 99%

ALMACAL VII: first interferometric number counts at 650 μm

Klitsch

Smail

Péroux

et al. 2020

Monthly Notices of the Royal Astronomical Society

Self Cite

View full text Add to dashboard Cite

show abstract

“…The extreme infrared luminosities observed in these submillimeter galaxies (SMGs) suggest that they are dusty and considered to be among the most intensively star-forming sources in the universe (Smail et al 1997;Barger et al 1998Barger et al , 1999Hughes et al 1998;Eales et al 1999). SMGs appear to have a redshift distribution peaking at z ; 2.5 with the majority of them at z=1.5-3.5 (Barger et al 2000;Chapman et al 2003Chapman et al , 2005Pope et al 2006;Aretxaga et al 2007;Wardlow et al 2011;Michałowski et al 2012bMichałowski et al , 2017Yun et al 2012;Simpson et al 2014Simpson et al , 2017Koprowski et al 2016;Danielson et al 2017;Dunlop et al 2017;Stach et al 2019;Dudzevičiūtė et al 2020), occupying the same putative peak epoch of unobscured star formation (Madau & Dickinson 2014) and active galactic nucleus (AGN) activity (Schmidt et al 1995;Hasinger et al 2005;Wall et al 2008;Assef et al 2011). The total infrared luminosities (L IR ; 8-1000 μm) of SMGs are similar to local ultra-luminous infrared galaxies (Sanders et al 1988;Sanders & Mirabel 1996;Farrah et al 2001;Armus et al 2009), reaching values greater than a few times 10 12 L ☉ or even higher than 10 13 L ☉ for some of the brightest sources.…”

Section: Introductionmentioning

confidence: 99%

“…The total infrared luminosities (L IR ; 8-1000 μm) of SMGs are similar to local ultra-luminous infrared galaxies (Sanders et al 1988;Sanders & Mirabel 1996;Farrah et al 2001;Armus et al 2009), reaching values greater than a few times 10 12 L ☉ or even higher than 10 13 L ☉ for some of the brightest sources. This corresponds to star formation rates (SFRs) ranging from around 100 M ☉ yr −1 to more than 1000 M ☉ yr −1 (Hainline et al 2011;Barger et al 2012;Swinbank et al 2014;da Cunha et al 2015;Simpson et al 2015;Dudzevičiūtė et al 2020).…”

Section: Introductionmentioning

confidence: 99%

“…Feedback mechanisms from star formation or black hole accretion could have injected sufficient energy to heat the remaining gas or expel it from the galaxy to prevent further star formation (Silk & Rees 1998;Fabian 1999;Trayford et al 2016). This scenario may be responsible for the formation of the most massive (M * >10 11 M ☉ ) elliptical galaxies in the local universe (Lilly et al 1999;Hopkins et al 2005;Simpson et al 2014;Toft et al 2014;Dudzevičiūtė et al 2020;Rennehan et al 2020). Therefore, the cosmological evolution of SMGs is crucial for our understanding of the formation of massive galaxies in the universe.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

SCUBA-2 Ultra Deep Imaging EAO Survey (STUDIES). IV. Spatial Clustering and Halo Masses of Submillimeter Galaxies

Lim

Chen

Smail

et al. 2020

ApJ

Self Cite

View full text Add to dashboard Cite

We analyze an extremely deep 450 μm image (1σ=0.56 mJy beam −1) of a ;300 arcmin 2 area in the CANDELS/ COSMOS field as part of the Sub-millimeter Common User Bolometric Array-2 Ultra Deep Imaging EAO Survey. We select a robust (signal-to-noise ratio 4) and flux-limited (4 mJy) sample of 164 submillimeter galaxies (SMGs) at 450 μm that have K-band counterparts in the COSMOS2015 catalog identified from radio or midinfrared imaging. Utilizing this SMG sample and the 4705 K-band-selected non-SMGs that reside within the noise level 1 mJy beam −1 region of the 450 μm image as a training set, we develop a machine-learning classifier using K-band magnitude and color-color pairs based on the 13-band photometry available in this field. We apply the trained machine-learning classifier to the wider COSMOS field (1.6 deg 2) using the same COSMOS2015 catalog and identify a sample of 6182 SMG candidates with similar colors. The number density, radio and/or mid-infrared detection rates, redshift and stellar-mass distributions, and the stacked 450 μm fluxes of these SMG candidates, from the S2COSMOS observations of the wide field, agree with the measurements made in the much smaller CANDELS field, supporting the effectiveness of the classifier. Using this SMG candidate sample, we measure the two-point autocorrelation functions from z=3 down to z=0.5. We find that the SMG candidates reside in halos with masses of ;(2.0±0.5)×10 13 h −1 M ☉ across this redshift range. We do not find evidence of downsizing that has been suggested by other recent observational studies.

show abstract

Understanding galaxy formation and evolution through an all-sky submillimetre spectroscopic survey

Negrello

Bonato

Cai

et al. 2020

Publ. Astron. Soc. Aust.

View full text Add to dashboard Cite

We illustrate the extraordinary discovery potential for extragalactic astrophysics of a far-infrared/submillimetre (far-IR/submm) all-sky spectroscopic survey with a 3-m-class space telescope. Spectroscopy provides a three-dimensional view of the Universe and allows us to take full advantage of the sensitivity of present-day instrumentation, close to fundamental limits, overcoming the spatial confusion that affects broadband far-IR/submm surveys. A space telescope of the 3-m class (which has already been described in recent papers) will detect emission lines powered by star formation in galaxies out to $z\,{\simeq}\,8$ . It will specifically provide measurements of spectroscopic redshifts, star-formation rates (SFRs), dust masses, and metal content for millions of galaxies at the peak epoch of cosmic star formation and of hundreds of them at the epoch of reionisation. Many of these star-forming galaxies will be strongly lensed; the brightness amplification and stretching of their sizes will make it possible to investigate (by means of follow-up observations with high-resolution instruments like ALMA, JWST, and SKA) their internal structure and dynamics on the scales of giant molecular clouds (40–100 pc). This will provide direct information on the physics driving the evolution of star-forming galaxies. Furthermore, the arcmin resolution of the telescope at submm wavelengths is ideal for detecting the cores of galaxy proto-clusters, out to the epoch of reionisation. Due to the integrated emission of member galaxies, such objects (as well as strongly lensed sources) will dominate at the highest apparent far-IR luminosities. Tens of millions of these galaxy-clusters-in-formation will be detected at $z \simeq 2 - 3$ –3, with a tail extending out to $z\,{\simeq}\,7$ , and thousands of detections at $6\,{<}\,z\,{<}\,7$ . Their study will allow us to track the growth of the most massive halos well beyond what is possible with classical cluster surveys (mostly limited to $z\,\lesssim\, 1.5 - 2$ –2), tracing the history of star formation in dense environments and teaching us how star formation and galaxy-cluster formation are related across all epochs. The obscured cosmic SFR density of the Universe will thereby be constrained. Such a survey will overcome the current lack of spectroscopic redshifts of dusty star-forming galaxies and galaxy proto-clusters, representing a quantum leap in far-IR/submm extragalactic astrophysics.

show abstract

An ALMA survey of the SCUBA-2 CLS UDS field: physical properties of 707 sub-millimetre galaxies

Cited by 236 publications

References 166 publications

ALMACAL VII: first interferometric number counts at 650 μm

ALMACAL VII: first interferometric number counts at 650 μm

SCUBA-2 Ultra Deep Imaging EAO Survey (STUDIES). IV. Spatial Clustering and Halo Masses of Submillimeter Galaxies

Understanding galaxy formation and evolution through an all-sky submillimetre spectroscopic survey

Contact Info

Product

Resources

About