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The Radio Galaxy Environment Reference Survey (RAGERS): a submillimetre study of the environments of massive radio-quiet galaxies at z = 1–3

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  • Thomas Cornish
  • Julie Wardlow
  • T. R. Greve
  • Scott C. Chapman
  • Chian-Chou Chen
  • H. Dannerbauer
  • Tomotsugu Goto
  • Bitten Gullberg
  • Luis Ho
  • Xue-Jian Jiang
  • Claudia Lagos
  • Lee Minju
  • Stephen Serjeant
  • Hyunjin Shim
  • Daniel J B Smith
  • Aswin Vijayan
  • Jeff Wagg
  • Dazhi Zhou
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<mark>Journal publication date</mark>30/09/2024
<mark>Journal</mark>Monthly Notices of the Royal Astronomical Society
Issue number1
Volume533
Number of pages13
Pages (from-to)1032-1044
Publication StatusPublished
Early online date9/08/24
<mark>Original language</mark>English

Abstract

Measuring the environments of massive galaxies at high redshift is crucial to understanding galaxy evolution and the conditions that gave rise to the distribution of matter we see in the Universe today. While high-z radio galaxies (HzRGs) and quasars tend to reside in protocluster-like systems, the environments of their radio-quiet counterparts are relatively unexplored, particularly in the submillimetre, which traces dust-obscured star formation. In this study we search for 850 μm-selected submillimetre galaxies in the environments of massive (M⋆>1011M⊙), radio-quiet (L500MHz≲1025 W Hz−1) galaxies at z∼1--3 using S2COSMOS data. By constructing number counts in circular regions of radius 1--6 arcmin and comparing with blank-field measurements, we find no significant overdensities of SMGs around massive radio-quiet galaxies at any of these scales, despite being sensitive down to overdensities of δ∼0.4. To probe deeper than the catalogue we also examine the distribution of peaks in the SCUBA-2 SNR map, which reveals only tentative signs of any difference in the SMG densities of the radio-quiet galaxy environments compared to the blank field, and only on smaller scales (1′ radii, corresponding to ∼0.5 Mpc) and higher SNR thresholds. We conclude that massive, radio-quiet galaxies at cosmic noon are typically in environments with δ≲0.4, which are either consistent with the blank field or contain only weak overdensities spanning sub-Mpc scales. The contrast between our results and studies of HzRGs with similar stellar masses and redshifts implies an intrinsic link between the wide-field environment and radio AGN luminosity at high redshift.