Nature of Faint Radio Sources in GOODS-North and GOODS-South Fields. I. Spectral Index and Radio–FIR Correlation

Gim, Hansung B.; Yun, Min S.; Owen, F. N.; Momjian, Emmanuel; Miller, Neal A.; Giavalisco, Mauro; Wilson, Grant; Lowenthal, James D.; Aretxaga, I.; Hughes, D. H.; Morrison, G.; Kawabe, Ryohei

doi:10.3847/1538-4357/ab1011

Cited by 27 publications

(39 citation statements)

References 99 publications

(188 reference statements)

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“…This imaging reaches a depth of 0.32 μJy beam −1 with an angular resolution of 0.61 x0.31 , ∼ 10 times deeper and ∼ 2 times higher resolution then comparable surveys (i.e. Delvecchio et al (2017); Gim et al (2019)). The data reduction and source extraction will be presented in Rujopakarn, in prep.…”

Section: Datamentioning

confidence: 65%

Connecting black holes and galaxies in faint radio populations at cosmic noon

Alberts

Rujopakarn

Rieke³

2019

Proc. IAU

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We leverage new ultra-deep, high resolution, multi-frequency radio imaging at 6 and 3 GHz with the unique datasets available in the GOODS-S/HUDF region in order to assess the AGN fraction in a faint radio-selected sample. For AGN identification, we adopt a multi-wavelength approach, combining X-ray and (mid-)infrared (IR) selections with radio identification such as X-ray to radio excess, flat radio spectral slopes, and the radio-IR correlation. We identify AGN in 43% of our radio sample, yielding an AGN source density of ∼ 1 arcmin−2. This AGN fraction is likely underestimated, as 1) our shallower 3 GHz data is biased against flat radio spectrum sources and 2) all of our selections may be biased against the most heavily obscured AGN. The James Webb Space Telescope’s Mid-Infrared Instrument (MIRI) will address the latter issue and we briefly outline our Cycle 1 Guaranteed Time Observation (GTO) program to search for heavily obscured AGN.

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Section: Datamentioning

confidence: 65%

Connecting black holes and galaxies in faint radio populations at cosmic noon

Alberts

Rujopakarn

Rieke³

2019

Proc. IAU

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“…Gim et al (2019) illustrate that not accounting for this intrinsic variation can result in both significantly higher scatter in the FIRRC and a potential bias. However, our results are unlikely to be significantly affected by this scatter due to the use of stacked samples, while the magnitude bias measured by Gim et al (2019, ∆q FIR = −0.061) is not large enough to affect our conclusions.…”

Section: Stellar Mass Rangementioning

confidence: 94%

“…Thirdly, in deriving the radio luminosity measurements we have assumed a constant canonical spectral slope of α = −0.8 (Condon 1992) when converting from flux to luminosity (or vice versa) throughout this work. Although this canonical value has been shown to be a valid assumption for the median spectral slope in SFGs out to high redshift (Calistro Rivera et al 2017;Gim et al 2019), there is still significant scatter around this value. Gim et al (2019) illustrate that not accounting for this intrinsic variation can result in both significantly higher scatter in the FIRRC and a potential bias.…”

Section: Stellar Mass Rangementioning

confidence: 96%

“…Although this canonical value has been shown to be a valid assumption for the median spectral slope in SFGs out to high redshift (Calistro Rivera et al 2017;Gim et al 2019), there is still significant scatter around this value. Gim et al (2019) illustrate that not accounting for this intrinsic variation can result in both significantly higher scatter in the FIRRC and a potential bias. However, our results are unlikely to be significantly affected by this scatter due to the use of stacked samples, while the magnitude bias measured by Gim et al (2019, ∆q FIR = −0.061) is not large enough to affect our conclusions.…”

Section: Stellar Mass Rangementioning

confidence: 96%

“…Given this close agreement, we choose not to apply any peak-tototal flux corrections to our forced radio flux measurements (the potential effects on our results of this assumption are discussed in Section 3.4). Finally, to allow direct comparison between our radio measurements and literature measurements of the SFR-radio relation at z ∼ 0, we convert our measured fluxes and luminosities from their central frequency of 1.525 GHz to 1.4 GHz assuming a spectral slope of α = −0.8 (a valid assumption for RC emission produced by star-formation, Calistro Rivera et al 2017;Gim et al 2019).…”

Section: Radio Continuum Imagingmentioning

confidence: 99%

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The MOSDEF Survey: calibrating the relationship between H α star formation rate and radio continuum luminosity at 1.4 < z < 2.6

Duncan

Shivaei

Shapley

et al. 2020

Monthly Notices of the Royal Astronomical Society

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The observed empirical relation between the star-formation rates (SFR) of low-redshift galaxies and their radio continuum luminosity offers a potential means of measuring SFR in high redshift galaxies that is unaffected by dust obscuration. In this study, we make the first test for redshift evolution in the SFR-radio continuum relation at high redshift using dust-corrected Hα SFR. Our sample consists of 178 galaxies from the MOSFIRE Deep Evolution Field (MOSDEF) Survey at 1.4 < z < 2.6 with rest-frame optical spectroscopy and deep 1.5 GHz radio continuum observations from the Karl G. Jansky Very Large Array (VLA) GOODS North field. Using a stacking analysis we compare the observed radio continuum luminosities with those predicted from the dust-corrected Hα SFR assuming a range of z ∼ 0 relations. We find no evidence for a systematic evolution with redshift, when stacking the radio continuum as a function of dust-corrected Hα SFR and when stacking both optical spectroscopy and radio continuum as a function of stellar mass. We conclude that locally calibrated relations between SFR and radio continuum luminosity remain valid out to z ∼ 2.

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Cosmic evolution of radio-excess active galactic nuclei in quiescent and star-forming galaxies across 0 < z < 4

Wang,

Liu

et al. 2024

A&A

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Radio-excess active galactic nuclei (radio-AGNs) are essential to our understanding of both the physics of black hole (BH) accretion and the interaction between BHs and host galaxies. Recent deep and wide radio continuum surveys have made it possible to study radio-AGNs down to lower luminosities and up to higher redshifts than previous studies, and are providing new insights into the abundance and physical origin of radio-AGNs. Here we focus on the cosmic evolution, physical properties, and AGN-host galaxy connections of radio-AGNs selected from a total sample of sim 400,000 galaxies at $0 < z < 4$ in the GOODS-N and COSMOS fields. Combining the deep radio continuum data with multi-band, de-blended far-infrared, and submillimeter data, we were able to identify 983 radio-AGNs out of the entire galaxy sample through radio excess relative to the far-infrared--radio relation. We studied the cosmic evolution of 1.4 GHz radio luminosity functions (RLFs) for both star-forming galaxies (SFGs) and radio-AGNs, which can be well described by a pure luminosity evolution of $L_ star z +3.57 $ and a pure density evolution of $ star z +2.69 $, respectively. We derived the turnover luminosity, above which the number density of radio-AGNs surpasses that of SFGs. We show that this crossover luminosity increases with increasing redshifts, from $10^ W Hz $ at $z 0$ to W Hz $ at $z 4$. At the full redshift range of $0 < z < 4$, we further derive the probability radio $) of SFGs and quiescent galaxies (QGs) hosting a radio-AGN, as a function of stellar mass ($M_ star $), radio luminosity ($L_ R $), and redshift ($z$), which yields $p_ radio star R $ for SFGs, and $p_ radio star R $ for QGs, respectively. The quantitative relation for the probabilities of galaxies hosting a radio-AGN indicates that radio-AGNs in QGs prefer to reside in more massive galaxies with higher $L_ R $ than those in SFGs. The fraction of radio-AGN increases toward higher redshift in both SFGs and QGs, with a more rapid increase in SFGs.

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Nature of Faint Radio Sources in GOODS-North and GOODS-South Fields. I. Spectral Index and Radio–FIR Correlation

Cited by 27 publications

References 99 publications

Connecting black holes and galaxies in faint radio populations at cosmic noon

Connecting black holes and galaxies in faint radio populations at cosmic noon

The MOSDEF Survey: calibrating the relationship between H α star formation rate and radio continuum luminosity at 1.4 < z < 2.6

Cosmic evolution of radio-excess active galactic nuclei in quiescent and star-forming galaxies across 0 < z < 4

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Nature of Faint Radio Sources in GOODS-North and GOODS-South Fields. I. Spectral Index and Radio–FIR Correlation

Cited by 27 publications

References 99 publications

Connecting black holes and galaxies in faint radio populations at cosmic noon

Connecting black holes and galaxies in faint radio populations at cosmic noon

The MOSDEF Survey: calibrating the relationship between H α star formation rate and radio continuum luminosity at 1.4 &lt; z &lt; 2.6

Cosmic evolution of radio-excess active galactic nuclei in quiescent and star-forming galaxies across 0 < z < 4

Contact Info

Product

Resources

About

The MOSDEF Survey: calibrating the relationship between H α star formation rate and radio continuum luminosity at 1.4 < z < 2.6