A Spectroscopic Follow-up Program of Very Massive Galaxies at 3 &lt; z &lt; 4: Confirmation of Spectroscopic Redshifts, and a High Fraction of Powerful AGNs

Marsan, Z. Cemile; Marchesini, Danilo; Brammer, Gabriel; Geier, S.; Kado-Fong, Erin; Labbé, Ivo; Muzzin, Adam; Stefanon, Mauro

doi:10.3847/1538-4357/aa7206

Cited by 42 publications

(45 citation statements)

References 100 publications

(177 reference statements)

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“…Most of the MIPS-bright galaxies are fit by templates with SFR > 100 M yr −1 , although in reality their IR emission may be caused not only by heated dust, but also (at least partly) by an active galactic nucleus (e.g. Casey et al 2014b;Marsan et al 2015Marsan et al , 2017. Figure A.2 summarises the changes described above, showing as a function of z the fraction of galaxies either excluded from the SMF computation (i.e.…”

Section: Appendix A: Photometric Redshifts In Cosmos2015mentioning

confidence: 95%

“…10). At z > 3, massive galaxies can also host an active black hole and disregarding its contribution in the SED fitting may cause a stellar mass overestimate of 0.1−0.3 dex (Hainline et al 2012;Marsan et al 2017). The impact of different AGN populations on the SMF shall be discussed in a future publication (Delvecchio et al, in prep.).…”

Section: Sources Of Uncertaintymentioning

confidence: 98%

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The COSMOS2015 galaxy stellar mass function

Davidzon

Ilbert

Laigle

et al. 2017

A&A

409

613

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We measure the stellar mass function (SMF) and stellar mass density of galaxies in the COSMOS field up to z ∼ 6. We select them in the near-IR bands of the COSMOS2015 catalogue, which includes ultra-deep photometry from UltraVISTA-DR2, SPLASH, and Subaru/Hyper SuprimeCam. At z > 2.5 we use new precise photometric redshifts with error σ z = 0.03(1 + z) and an outlier fraction of 12%, estimated by means of the unique spectroscopic sample of COSMOS (∼100 000 spectroscopic measurements in total, more than one thousand having robust z spec > 2.5). The increased exposure time in the DR2, along with our panchromatic detection strategy, allow us to improve the completeness at high z with respect to previous UltraVISTA catalogues (e.g. our sample is >75% complete at 10 10 M and z = 5). We also identify passive galaxies through a robust colour-colour selection, extending their SMF estimate up to z = 4. Our work provides a comprehensive view of galaxy-stellar-mass assembly between z = 0.1 and 6, for the first time using consistent estimates across the entire redshift range. We fit these measurements with a Schechter function, correcting for Eddington bias. We compare the SMF fit with the halo mass function predicted from ΛCDM simulations, finding that at z > 3 both functions decline with a similar slope in the high-mass end. This feature could be explained assuming that mechanisms quenching star formation in massive haloes become less effective at high redshifts; however further work needs to be done to confirm this scenario. Concerning the SMF low-mass end, it shows a progressive steepening as it moves towards higher redshifts, with α decreasing from −1.47 +0.02 −0.02 at z 0.1 to −2.11 +0.30 −0.13 at z 5. This slope depends on the characterisation of the observational uncertainties, which is crucial to properly remove the Eddington bias. We show that there is currently no consensus on the method to quantify such errors: different error models result in different best-fit Schechter parameters.

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Section: Appendix A: Photometric Redshifts In Cosmos2015mentioning

confidence: 95%

Section: Sources Of Uncertaintymentioning

confidence: 98%

The COSMOS2015 galaxy stellar mass function

Davidzon

Ilbert

Laigle

et al. 2017

A&A

409

613

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“…Spectroscopic redshifts also exist for ∼ 7.1 × 10 4 galaxies, from the latest compilation by M. Salvato et al (version Sept. 1st, 2017; available internally in the COSMOS collaboration), which includes almost all spectroscopic observations in the COSMOS field: Lilly et al (2007Lilly et al ( , 2009; zCOSMOS Survey; with VLT/VI-MOS); Fu et al (2010; with Spitzer/IRS); Casey et al (2012Casey et al ( , 2017 with Keck II/DEIMOS); Comparat et al (2015; with VLT/FORS2); Le Fèvre et al (2015) and Tasca et al (2017) (VUDS Survey; with VLT/VMOS); Hasinger et al (2018; with Keck II/DEIMOS); Kriek et al (2015;MOSDEF Survey; with Keck I/MOSFIRE); Marsan et al (2017; with Keck II/NIRSPEC); Masters et al (2017; with Keck II/DEIMOS); Nanayakkara et al (2016; with Keck I/MOSFIRE); Silverman et al (2015a;FMOS-COSMOS Survey; with Subaru/FMOS); van der Wel et al (2016; LEGA-C Survey; with VLT/VMOS); Yun et al (2015; with LMT/RSR) (listed only references whose spectroscopic redshifts are used in this work).…”

Section: Data and Photometrymentioning

confidence: 99%

Automated Mining of the ALMA Archive in the COSMOS Field (A³COSMOS). I. Robust ALMA Continuum Photometry Catalogs and Stellar Mass and Star Formation Properties for ∼700 Galaxies at z = 0.5–6

Liu

Lang

Magnelli

et al. 2019

ApJS

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The rich information on (sub-)millimeter dust continuum emission from distant galaxies in the public Atacama Large Millimeter/submillimeter Array (ALMA) archive is contained in thousands of inhomogeneous observations from individual PI-led programs. To increase the usability of these data for studies deepening our understanding of galaxy evolution, we have developed automated mining pipelines for the ALMA archive in the COSMOS field (A3COSMOS) which efficiently exploit the available information for large numbers of galaxies across cosmic time, and keep the data products in sync with the increasing public ALMA archive: (a) a dedicated ALMA continuum imaging pipeline; (b) two complementary photometry pipelines for both blind source extraction and prior source fitting; (c) a counterpart association pipeline utilizing the multi-wavelength data available (including quality assessment based on machine-learning techniques); (d) an assessment of potential (sub-)mm line contribution to the measured ALMA continuum; and (e) extensive simulations to provide statistical corrections to biases and uncertainties in the ALMA continuum measurements. Application of these tools yields photometry catalogs with ∼ 1000 (sub-)mm detections (spurious fraction ∼ 8 − 12%) from over 1500 individual ALMA continuum images. Combined with ancillary photometric and redshift catalogs and the above quality assessments, we provide robust information on redshift, stellar mass and star formation rate for ∼700 galaxies at redshifts 0.5-6 in the COSMOS field (with undetermined selection function). The ALMA photometric measurements and galaxy properties are released publicly within our blind-extraction, prior-fitting and galaxy property catalogs, plus the images. These products will be updated on a regular basis in the future. A 3 COSMOS ALMA Continuum Images (Sect. 2.1) Multi-wavelength Catalogs (Sect. 2.3) Monte Carlo Simulations (Sect. 3) combine COSMOS master catalog (Sect. 2.3) Blind source extraction (PyBDSF; Sect. 2.2) Prior source fitting (get-pix+galfit; Sect. 2.4) Meta data Prior extraction catalog Blind extraction catalog apply sim. corr. apply sim. corr.

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“…Let us finally comment on the number counts of these extreme systems. D13 calculated the predicted galaxy number counts for a variety of approaches, including fully theoretical cosmological simulations (as per the Millennium Simulation), semi-empirical predictions obtained by passively evolving the z = 0 and 0.5 < z < 0.7 published mass functions to higher redshift, available high-z mass functions (Marchesini et al 2010), and also results from abundance-matching techniques (Behroozi et al 2013). For example, empirical mass functions do forecast the presence of ∼ 7000 galaxies with log(M * /M ) ≥ 12.0 within the whole DES.…”

Section: Conclusion and Discussionmentioning

confidence: 99%

“…In order to bridge the fossil record with the formation event and trace galaxy evolution over cosmic time, many works have attacked the problem in a statistical sense, by probing number density evolution as a function of galaxy mass. Studies of the galaxy mass function over the past decade reached the uniform conclusion that the abundance of the most massive galaxies (M/M > 10 11.5 ) hardly evolves since z ∼ 1 (Cimatti, Daddi & Renzini 2006;Wake et al 2006;Pozzetti et al 2010;Marchesini et al 2010;Muzzin et al 2013;Gonzalez-Perez et al 2009;Mortlock et al 2015). One caveat to these studies has been that the observational database was drawn from small area, deep surveys, which carry the problem of cosmic variance.…”

Section: Introductionmentioning

confidence: 99%

Candidate massive galaxies atz ∼ 4 in the Dark Energy Survey

Guarnieri

Maraston

Thomas

et al. 2018

Monthly Notices of the Royal Astronomical Society

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Using stellar population models, we predicted that the Dark Energy Survey (DES)due to its special combination of area (5000 deg.sq.) and depth (i = 24.3) -would be in the position to detect massive ( 10 11 M ) galaxies at z ∼ 4. We confront those theoretical calculations with the first ∼ 150 deg. sq. of DES data reaching nominal depth. From a catalogue containing ∼ 5 million sources, ∼ 26000 were found to have observed-frame g−r vs r−i colours within the locus predicted for z ∼ 4 massive galaxies. We further removed contamination by stars and artefacts, obtaining 606 galaxies lining up by the model selection box. We obtained their photometric redshifts and physical properties by fitting model templates spanning a wide range of star formation histories, reddening and redshift. Key to constrain the models is the addition, to the optical DES bands g, r, i, z, and Y , of near-IR J, H, K s data from the Vista Hemisphere Survey. We further applied several quality cuts to the fitting results, including goodness of fit and a unimodal redshift probability distribution. We finally select 233 candidates whose photometric redshift probability distribution function peaks around z ∼ 4, have high stellar masses (log(M * /M ) ∼ 11.7 for a Salpeter IMF) and ages around 0.1 Gyr, i.e. formation redshift around 5. These properties match those of the progenitors of the most massive galaxies in the local universe. This is an ideal sample for spectroscopic follow-up to select the fraction of galaxies which is truly at high redshift. These initial results and those at the survey completion, which we shall push to higher redshifts, will set unprecedented constraints on galaxy formation, evolution, and the re-ionisation epoch.

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A Spectroscopic Follow-up Program of Very Massive Galaxies at 3 < z < 4: Confirmation of Spectroscopic Redshifts, and a High Fraction of Powerful AGNs

Cited by 42 publications

References 100 publications

The COSMOS2015 galaxy stellar mass function

The COSMOS2015 galaxy stellar mass function

Automated Mining of the ALMA Archive in the COSMOS Field (A³COSMOS). I. Robust ALMA Continuum Photometry Catalogs and Stellar Mass and Star Formation Properties for ∼700 Galaxies at z = 0.5–6

Candidate massive galaxies atz ∼ 4 in the Dark Energy Survey

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A Spectroscopic Follow-up Program of Very Massive Galaxies at 3 < z < 4: Confirmation of Spectroscopic Redshifts, and a High Fraction of Powerful AGNs

Cited by 42 publications

References 100 publications

The COSMOS2015 galaxy stellar mass function

The COSMOS2015 galaxy stellar mass function

Automated Mining of the ALMA Archive in the COSMOS Field (A3COSMOS). I. Robust ALMA Continuum Photometry Catalogs and Stellar Mass and Star Formation Properties for ∼700 Galaxies at z = 0.5–6

Candidate massive galaxies atz ∼ 4 in the Dark Energy Survey

Contact Info

Product

Resources

About

Automated Mining of the ALMA Archive in the COSMOS Field (A³COSMOS). I. Robust ALMA Continuum Photometry Catalogs and Stellar Mass and Star Formation Properties for ∼700 Galaxies at z = 0.5–6