Mapping Obscuration to Reionization with ALMA (MORA): 2 mm Efficiently Selects the Highest-redshift Obscured Galaxies

Casey, Caitlin M.; Zavala, Jorge A.; Manning, Sinclaire M.; Aravena, M.; Béthermin, M.; Caputi, K.; Champagne, Jaclyn B.; Clements, D. L.; Drew, Patrick; Finkelstein, Steven L.; Fujimoto, Seiji; Hayward, Christopher C.; Koekemoer, Anton M.; Kokorev, Vasily; Lagos, Claudia del P.; Long, Arianna S.; Magdis, G.; Man, Allison; Mitsuhashi, Ikki; Popping, Gergö; Spilker, Justin; Staguhn, Johannes; Talia, M.; Toft, Sune; Treister, Ezequiel; Weaver, John R.; Yun, Min S.

doi:10.3847/1538-4357/ac2eb4

Cited by 50 publications

(56 citation statements)

References 197 publications

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“…Nevertheless, our data can be used to compare galaxyintegrated Rayleigh-Jeans slopes to other high-z samples and commonly adopted literature values of β for high-z data sets of similar quality. Here, our finding of 〈β〉 = 2.4 ± 0.3 suggests that the distribution of integrated β indices skews high, in line with other recent works, including a well-studied galaxy in SSA22 with β = 2.3 (Kato et al 2018) as well as other samples with dust continuum data at λ obs  2 mm (Jin et al 2019;Casey et al 2021). The aggregate best-fit SED results for our sample (see Table 2) show relatively steep β values ranging from 1.8 < β < 3.0, all steeper than the standard value often adopted in the literature, typically β = 1.8 (e.g., Scoville et al 2016), justified by measurements of the β from the Milky Way's ISM (e.g., Paradis et al 2009;Planck Collaboration et al 2011).…”

Section: Emissivity Spectral Indexsupporting

confidence: 92%

“…While the redshift distribution of galaxies selected at 2 mm is expected to be relatively high with 〈z〉 ≈ 3.6 (Casey et al 2021), the selection of these targets at 850 μm leads to a lower median redshift, consistent with what has been previously found for 850 μm-selected DSFGs (e.g., Dudzevičiūtė et al 2020;da Cunha et al 2021). Though we expect the follow up 2 mm observations to filter out lower-redshift sources (Casey et al 2021;Zavala et al 2021;Manning et al 2022), our source selection here is based on 850 μm, and thus for this study the redshift distribution is reflective of the 850 μm DSFG redshift distribution. Previous millimeter studies demonstrate that deeper surveys tend to select for lower-redshift DSFGs; in other words brighter DSFGs tend to sit at higher redshifts (e.g., Béthermin et al 2015).…”

Section: = -+supporting

confidence: 87%

“…Predictions from the SHARK model (Lagos et al 2020) are also in line with this observation. The MORA survey-the largest ALMA 2 mm blank-field contiguous survey (184 arcmin 2 )-demonstrates this, finding an average redshift z 3.6 0.3 0.4 á ñ = -+ , with 77% of sources at z > 3 and 30% at z > 4, effectively filtering out lower-redshift DSFGs (Casey et al 2021). Other millimeter wavelengths have been leveraged to select for higher-redshift sources; for example, (Zavala et al 2018a,) conduct a blind search at 3 mm and detect 16 sources at >5σ, and Williams et al (2019) serendipitously discover a z ∼ 5-6 source at similar wavelengths.…”

Section: Introductionmentioning

confidence: 92%

“…For example, Koprowski et al (2017), Rowan-Robinson et al (2016), Dudzevičiūtė et al (2020), and Gruppioni et al (2020) all present very different conclusions on the number density of IR-luminous galaxies at z > 3, due to either limited sample sizes at high redshift or fundamental differences in survey strategy. Additionally, using a blankfield 2 mm Atacama Large Millimeter/submillimeter Array (ALMA) survey (Mapping Obscuration to Reionization with ALMA, or MORA), Zavala et al (2021) and Casey et al (2021) found that DSFGs contribute ∼35% at z = 5 and only 20%-25% at z = 6-7, suggesting dust-obscured star formation plays a minor role in total star formation at early epochs. On the other hand, Gruppioni et al (2020) find a flatter IR luminosity function (IRLF) slope from 4.5 < z < 6, with a significant contribution to the CSFRD from obscured sources at high redshift, though again, using a very different survey strategy.…”

Section: Introductionmentioning

confidence: 99%

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Searching Far and Long. I. Pilot ALMA 2 mm Follow-up of Bright Dusty Galaxies as a Redshift Filter

Cooper

Casey

Zavala

et al. 2022

ApJ

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A complete census of dusty star-forming galaxies (DSFGs) at early epochs is necessary to constrain the obscured contribution to the cosmic star formation rate density (CSFRD); however, DSFGs beyond z ∼ 4 are both rare and hard to identify from photometric data alone due to degeneracies in submillimeter photometry with redshift. Here, we present a pilot study obtaining follow-up Atacama Large Millimeter Array (ALMA) 2 mm observations of a complete sample of 39 850 μm-bright dusty galaxies in the SSA22 field. Empirical modeling suggests 2 mm imaging of existing samples of DSFGs selected at 850 μm—1 mm can quickly and easily isolate the “needle in a haystack” DSFGs that sit at z > 4 or beyond. Combining archival submillimeter imaging with our measured ALMA 2 mm photometry (1σ ∼ 0.08 mJy beam−1 rms), we characterize the galaxies’ IR spectral energy distributions (SEDs) and use them to constrain redshifts. With available redshift constraints fit via the combination of six submillimeter bands, we identify 6/39 high-z candidates each with >50% likelihood to sit at z > 4, and find a positive correlation between redshift and 2 mm flux density. Specifically, our models suggest the addition of 2 mm to a moderately constrained IR SED will improve the accuracy of a millimeter-derived redshift from Δz/(1 + z) = 0.3 to Δz/(1 + z) = 0.2. Our IR SED characterizations provide evidence for relatively high-emissivity spectral indices (〈β〉 = 2.4 ± 0.3) in the sample. We measure that especially bright (S 850μ m > 5.55 mJy) DSFGs contribute ∼10% to the cosmic-averaged CSFRD from 2 < z < 5, confirming findings from previous work with similar samples.

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Section: Emissivity Spectral Indexsupporting

confidence: 92%

Section: = -+supporting

confidence: 87%

Section: Introductionmentioning

confidence: 92%

Section: Introductionmentioning

confidence: 99%

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Searching Far and Long. I. Pilot ALMA 2 mm Follow-up of Bright Dusty Galaxies as a Redshift Filter

Cooper

Casey

Zavala

et al. 2022

ApJ

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“…The median emissivity, β = 1.96 is fully consistent with several recent publications that find similarly steep values for the emissivity spectral index in various high-redshift galaxies with high quality far-IR constraints (e.g. Kato et al 2018;Casey et al 2021). We choose to adopt these priors because the minority of galaxies which produce unphysical fits when run with flat priors have more physical fits using normal priors.…”

Section: A1 Choice Of Parameter Priorssupporting

confidence: 80%

No Redshift Evolution of Dust Temperatures from $0 < z < 2$

Drew,

Casey

2022

Preprint

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Some recent literature has claimed there to be an evolution in galaxies' dust temperatures towards warmer (or colder) spectral energy distributions (SEDs) between low and high redshift. These conclusions are driven by both theoretical models and empirical measurement. Such claims sometimes contradict one another and are prone to biases in samples or SED fitting techniques. What has made direct comparisons difficult is that there is no uniform approach to fitting galaxies' infrared/millimeter SEDs. Here we aim to standardize the measurement of galaxies' dust temperatures with a python-based SED fitting procedure, MCIRSED a . We draw on reference datasets observed by IRAS, Herschel, and Scuba-2 to test for redshift evolution out to z ∼ 2. We anchor our work to the L IR -λ peak plane, where there is an empirically observed anti-correlation between IR luminosity and rest-frame peak wavelength (an observational proxy for luminosity-weighted dust temperature) such that λ peak = λ t (L IR /L t ) η where η = −0.09±0.01, L t = 10 12 L , and λ t = 92±2 µm. We find no evidence for redshift evolution of galaxies' temperatures, or λ peak , at fixed L IR from 0 < z < 2 with >99.99% confidence. Our finding does not preclude evolution in dust temperatures at fixed stellar mass, which is expected from a non-evolving L IR -λ peak relation and a strongly evolving SFR-M relation. The breadth of dust temperatures (σ log λ peak ) at a given L IR is likely driven by variation in galaxies' dust geometries and sizes and does not evolve. Testing for L IR -λ peak evolution toward higher redshift (z ∼ 5 − 6) requires better sampling of galaxies' dust SEDs near their peaks (observed ∼200-600 µm) with < ∼ 1 mJy sensitivity. This poses a significant challenge to current instrumentation.

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COSMOS2020: The galaxy stellar mass function

Weaver¹,

Davidzon²,

Toft³

et al. 2023

A&A

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Context. How galaxies form, assemble, and cease their star formation is a central question within the modern landscape of galaxy evolution studies. These processes are indelibly imprinted on the galaxy stellar mass function (SMF), and its measurement and understanding is key to uncovering a unified theory of galaxy evolution. Aims. We present constraints on the shape and evolution of the galaxy SMF, the quiescent galaxy fraction, and the cosmic stellar mass density across 90% of the history of the Universe from z = 7.5 → 0.2 as a means to study the physical processes that underpin galaxy evolution. Methods. The COSMOS survey is an ideal laboratory for studying representative galaxy samples. Now equipped with deeper and more homogeneous near-infrared coverage exploited by the COSMOS2020 catalog, we leverage the large 1.27 deg2 effective area to improve sample statistics and understand spatial variations (cosmic variance) – particularly for rare, massive galaxies – and push to higher redshifts with greater confidence and mass completeness than previous studies. We divide the total stellar mass function into star-forming and quiescent subsamples through NUVrJ color-color selection. The measurements are then fit with single- and double-component Schechter functions to infer the intrinsic galaxy stellar mass function, the evolution of its key parameters, and the cosmic stellar mass density out to z = 7.5. Finally, we compare our measurements to predictions from state-of-the-art cosmological simulations and theoretical dark matter halo mass functions. Results. We find a smooth, monotonic evolution in the galaxy stellar mass function since z = 7.5, in general agreement with previous studies. The number density of star-forming systems have undergone remarkably consistent growth spanning four decades in stellar mass from z = 7.5 → 2 whereupon high-mass systems become predominantly quiescent (“downsizing”). Meanwhile, the assembly and growth of low-mass quiescent systems only occurred recently, and rapidly. An excess of massive systems at z ≈ 2.5 − 5.5 with strikingly red colors, with some being newly identified, increase the observed number densities to the point where the SMF cannot be reconciled with a Schechter function. Conclusions. Systematics including cosmic variance and/or active galactic nuclei contamination are unlikely to fully explain this excess, and so we speculate that they may be dust-obscured populations similar to those found in far infrared surveys. Furthermore, we find a sustained agreement from z ≈ 3 − 6 between the stellar and dark matter halo mass functions for the most massive systems, suggesting that star formation in massive halos may be more efficient at early times.

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Mapping Obscuration to Reionization with ALMA (MORA): 2 mm Efficiently Selects the Highest-redshift Obscured Galaxies

Cited by 50 publications

References 197 publications

Searching Far and Long. I. Pilot ALMA 2 mm Follow-up of Bright Dusty Galaxies as a Redshift Filter

Searching Far and Long. I. Pilot ALMA 2 mm Follow-up of Bright Dusty Galaxies as a Redshift Filter

No Redshift Evolution of Dust Temperatures from $0 < z < 2$

COSMOS2020: The galaxy stellar mass function

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