17 research outputs found

    Constraints on galaxy formation from the cosmic-infrared-background − \,-\,optical-imaging cross-correlation using Herschel\boldsymbol{Herschel} and UNIONS

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    Using Herschel\it{Herschel}-SPIRE imaging and the Canada-France Imaging Survey (CFIS) Low Surface Brightness data products from the Ultraviolet Near-Infrared Optical Northern Survey (UNIONS), we present a cross-correlation between the cosmic infrared background and cosmic optical background fluctuations. With a combined sky area of 91 deg291\,{\rm deg}^2 and a minimum resolved scale of 18 18\,arcsec, the cross-spectrum is measured for two cases: all galaxies are kept in the images; or all individually-detected galaxies are masked to produce `background' maps. We report the detection of the cross-correlation signal at ≳22 σ\gtrsim 22\,\sigma (≳18 σ\gtrsim 18\,\sigma for the background map). The part of the optical brightness variations that are correlated with the submm emission translates to an rms brightness of ≃32.5 mag arcsec−2\simeq 32.5\,{\rm mag}\,{\rm arcsec}^{-2} in the rr band, a level normally unreachable for individual sources. A critical issue is determining what fraction of the cross-power spectrum might be caused by emission from Galactic cirrus. For one of the fields, the Galactic contamination is approximately a factor of 10 higher than the extragalactic signal, with the contamination being estimated using a linear regression from several external survey maps; however, for the other fields, the contamination is typically around 20 per cent. An additional discriminant is that the cross-power spectrum is of the approximate form P(k)∝1/kP(k)\propto 1/k, much shallower than that of Galactic cirrus. We interpret the results in a halo-model framework, which shows good agreement with independent measurements for the scalings of star-formation rates in galaxies. The approach presented in this study holds great promise for future surveys such as FYST/CCAT-prime combined with Euclid{\it Euclid} or the Vera Rubin Observatory (LSST), which will enable a detailed exploration of the evolution of star formation in galaxies

    Constraints on galaxy formation from the cosmic-infrared-background − \,-\,optical-imaging cross-correlation using Herschel\boldsymbol{Herschel} and UNIONS

    No full text
    Using Herschel\it{Herschel}-SPIRE imaging and the Canada-France Imaging Survey (CFIS) Low Surface Brightness data products from the Ultraviolet Near-Infrared Optical Northern Survey (UNIONS), we present a cross-correlation between the cosmic infrared background and cosmic optical background fluctuations. With a combined sky area of 91 deg291\,{\rm deg}^2 and a minimum resolved scale of 18 18\,arcsec, the cross-spectrum is measured for two cases: all galaxies are kept in the images; or all individually-detected galaxies are masked to produce `background' maps. We report the detection of the cross-correlation signal at ≳22 σ\gtrsim 22\,\sigma (≳18 σ\gtrsim 18\,\sigma for the background map). The part of the optical brightness variations that are correlated with the submm emission translates to an rms brightness of ≃32.5 mag arcsec−2\simeq 32.5\,{\rm mag}\,{\rm arcsec}^{-2} in the rr band, a level normally unreachable for individual sources. A critical issue is determining what fraction of the cross-power spectrum might be caused by emission from Galactic cirrus. For one of the fields, the Galactic contamination is approximately a factor of 10 higher than the extragalactic signal, with the contamination being estimated using a linear regression from several external survey maps; however, for the other fields, the contamination is typically around 20 per cent. An additional discriminant is that the cross-power spectrum is of the approximate form P(k)∝1/kP(k)\propto 1/k, much shallower than that of Galactic cirrus. We interpret the results in a halo-model framework, which shows good agreement with independent measurements for the scalings of star-formation rates in galaxies. The approach presented in this study holds great promise for future surveys such as FYST/CCAT-prime combined with Euclid{\it Euclid} or the Vera Rubin Observatory (LSST), which will enable a detailed exploration of the evolution of star formation in galaxies

    High-resolution SMA imaging of bright submillimetre sources from the SCUBA-2 Cosmology Legacy Survey

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    We have used the Submillimeter Array (SMA) at 860 ”m to observe the brightest sources in the Submillimeter Common User Bolometer Array-2 (SCUBA-2) Cosmology Legacy Survey (S2CLS). The goal of this survey is to exploit the large field of the S2CLS along with the resolution and sensitivity of the SMA to construct a large sample of these rare sources and to study their statistical properties. We have targeted 70 of the brightest single-dish SCUBA-2 850 ”m sources down to S850 ≈ 8 mJy, achieving an average synthesized beam of 2.4 arcsec and an average rms of σ860 = 1.5 mJy beam−1 in our primary beam-corrected maps. We searched our SMA maps for 4σ peaks, corresponding to S860 6 mJy sources, and detected 62, galaxies, including three pairs. We include in our study 35 archival observations, bringing our sample size to 105 bright single-dish submillimetre sources with interferometric followup. We compute the cumulative and differential number counts, finding them to overlap with previous single-dish survey number counts within the uncertainties, although our cumulative number count is systematically lower than the parent S2CLS cumulative number count by 14 ± 6 per cent between 11 and 15 mJy. We estimate the probability that a 10 mJy singledish submillimetre source resolves into two or more galaxies with similar flux densities to be less than 15 per cent. Assuming the remaining 85 per cent of the targets are ultraluminous starburst galaxies between z = 2 and 3, we find a likely volume density of 400 M yr−1 sources to be ∌ 3+0.7 −0.6 × 10−7 Mpc−3. We show that the descendants of these galaxies could be 4 × 1011 M local quiescent galaxies, and that about 10 per cent of their total stellar mass would have formed during these short bursts of star formation
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