Fundamental differences in the radio properties of red and blue quasars: insight from the LOFAR Two-metre Sky Survey (LoTSS)

Rosario, D. J.; Fawcett, V. A.; Klindt, L.; Alexander, D. M.; Morabito, L. K.; Fotopoulou, S.; Lusso, Elisabeta; Rivera, G. Calistro

doi:10.1093/mnras/staa866

Cited by 39 publications

(94 citation statements)

References 61 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In this work we show how the results of Rosario et al (2020) and Fawcett et al (2020) support a picture in which both the most radio loud quasars or QSOs and the most radio quiet quasars or QSOs result from accretion onto rapidly rotating black holes in retrograde and prograde configurations, respectively. Intrinsic to this picture is the fact that retrograde accretion spins black holes toward prograde accretion, implying that radio loud quasars, if formed, constitute initial states, but never final ones.…”

Section: Introductionsupporting

confidence: 66%

“…We will show how to understand that feature as well as the tendency of the rQSOs to cQSOs ratio to peak in the radio loud range as shown in Figure 1. Rosario et al (2020). While the numbers approach unity at the extremes of radio loudness, they differ from that significantly in the middle.…”

Section: Discussionmentioning

confidence: 92%

“…In Figure 1 we reproduce the ratio of the numbers of rQSOs and cQSOs of Rosario et al (2020) as a function of radio loudness. As pointed out in their work, the ratio is significantly removed from value unity toward the radio loud/radio quiet boundary or midpoint of Figure 1 shown with a dashed line.…”

Section: Discussionmentioning

confidence: 99%

“…As pointed out in their work, the ratio is significantly removed from value unity toward the radio loud/radio quiet boundary or midpoint of Figure 1 shown with a dashed line. The values of Figure 1 come from the numbers of rQSOs and cQSOs from Rosario et al (2020) and which we separately show in Figure 2. Because the numbers reflect 6 micron, redshift matched, LOFAR detections, the actual distributions are enhanced with respect to Figure 2.…”

Section: Discussionmentioning

confidence: 99%

“…While the numbers approach unity at the extremes of radio loudness, they differ from that significantly in the middle. Rosario et al (2020), the ratio of which is plotted in Figure 1. Data points are smoothly connected for ease of comparison.…”

Section: Discussionmentioning

confidence: 99%

See 4 more Smart Citations

Evidence for Radio Loud to Radio Quiet Evolution from Red and Blue Quasars

Garofalo

Bishop

2020

PASP

View full text Add to dashboard Cite

Recent work on red and blue quasi-stellar objects (QSOs) has identified peculiar number distributions as a function of radio loudness that we explore and attempt to explain from the perspective of a picture in which a subset of the population of active galaxies evolves from the radio loud to the radio quiet state. Because the time evolution is slowed down by an order of magnitude or more for the radio quiet phase, the numbers of red and blue QSOs approach each other at the extreme end of the radio quiet range of radio loudness with larger numbers. The rapid time evolution of most radio loud phases, instead, makes the numbers similar but lower at the far radio loud end. At the midpoint of radio loudness, instead, the differences between red and blue QSOs experience their largest values which results from accretion rapidly spinning black holes down but subsequently spinning them up more slowly. Recovering these basic features of the observations is evidence for rapid evolution away from radio loudness and slow evolution in radio quiet states.

show abstract

Section: Introductionsupporting

confidence: 66%

Section: Discussionmentioning

confidence: 92%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

See 3 more Smart Citations

Evidence for Radio Loud to Radio Quiet Evolution from Red and Blue Quasars

Garofalo

Bishop

2020

PASP

View full text Add to dashboard Cite

show abstract

What is the origin of the stacked radio emission in radio-undetected quasars?

Retana-Montenegro

2022

A&A

View full text Add to dashboard Cite

Radio emission in the brightest radio quasars can be attributed to processes inherent to active galactic nuclei (AGN) powered by super massive black holes (SMBHs), while the physical origins of the radio fluxes in quasars without radio detections have not been established with full certainly. Deep radio surveys carried out with the Low Frequency ARray (LOFAR) are at least one order of magnitude more sensitive for objects with typical synchrotron spectra than previous wide-area high-frequency surveys ( > 1.0 GHz). With the enhanced sensitivity that LOFAR offers, we investigate the radio-infrared continuum of LOFAR radio-detected quasars (RDQs) and LOFAR radio-undetected quasars (RUQs) in the 9.3 deg2 NOAO Deep Wide-field survey (NDWFS) of the Boötes field; RUQs are quasars that are individually undetected at a level of ≥5σ in the LOFAR observations. To probe the nature of the radio and infrared emission, where direct detection is not possible due to the flux density limits, we used a median image stacking procedure. This was done in the radio frequencies of 150 MHz, 325 MHz, 1.4 GHz and 3.0 GHz, and in nine infrared bands between 8 and 500 μm. The stacking analysis allows us to probe the radio-luminosity for quasars that are up to one order of magnitude fainter than the ones detected directly. The radio and infrared photometry allow us to derive the median spectral energy distributions of RDQs and RUQs in four contiguous redshift bins between 0 < z < 6.15. The infrared photometry is used to derive the infrared star-formation rate (SFR) through SED fitting, and is compared with two independent radio-based star-formation (SF) tracers using the far-infrared radio correlation (FIRC) of star-forming galaxies. We find a good agreement between our radio and infrared SFR measurements and the predictions of the FIRC. Moreover, we use the FIRC predictions to establish the level of the contribution due to SMBH accretion to the total radio-luminosity. We show that SMBH accretion can account for ∼5−41% of the total radio-luminosity in median RUQs, while for median RDQs the contribution is ∼50−84%. This implies that vigorous SF activity is coeval with SMBH growth in our median stacked quasars. We find that median RDQs have higher SFRs that agree well with those of massive star-forming main sequence galaxies, while median RUQs present lower SFRs than RDQs. Furthermore, the behavior of the radio-loudness parameter (R = log10(Lrad/LAGN)) is investigated. For quasars with R ≥ −4.5, the radio-emission is consistent with being dominated by SMBH accretion, while for low radio luminosity quasars with R < −4.5 the relative contribution of SF to the radio fluxes increases as the SMBH component becomes weaker. We also find signatures of SF suppression due to negative AGN feedback in the brightest median RDQs at 150 MHz. Finally, taking advantage of our broad spectral coverage, we studied the radio spectra of median RDQs and RUQs. The spectral indices of RUQs and RDQs do not evolve significantly with redshift, but they become flatter towards lower frequencies.

show abstract

The multiwavelength properties of red QSOs: Evidence for dusty winds as the origin of QSO reddening

Rivera

Alexander

Rosario

et al. 2021

A&A

Self Cite

View full text Add to dashboard Cite

Fundamental differences in the radio properties of red quasars (QSOs), as compared to blue QSOs, have been recently discovered, positioning them as a potential key population in the evolution of galaxies and black holes across cosmic time. To elucidate the nature of these objects, we exploited a rich compilation of broad-band photometry and spectroscopic data to model their spectral energy distributions (SEDs) from the ultraviolet to the far-infrared and characterise their emission-line properties. Following a systematic comparison approach, we characterise the properties of the QSO accretion, obscuration, and host galaxies in a sample of ∼1800 QSOs at 0.2 < z < 2.5, classified into red and control QSOs and matched in redshift and luminosity. We find no strong differences in the average multiwavelength SEDs of red and control QSOs, other than the reddening of the accretion disk expected by the colour selection. Additionally, no clear link can be recognised between the reddening of QSOs and the interstellar medium as well as star formation properties of their host galaxies. Our modelling of the infrared emission using dusty torus models suggests that the dust distributions and covering factors in red QSOs are strikingly similar to those of the control sample, inferring that the reddening is not related to the torus and orientation effects. Interestingly, we detect a significant excess of infrared emission at rest-frame 2−5 μm, which shows a direct correlation with optical reddening. To explain its origin, we investigated the presence of outflow signatures in the QSO spectra, discovering a higher incidence of broad [O III] wings and high C IV velocity shifts (> 1000 km s−1) in red QSOs as compared to the control sample. We find that red QSOs that exhibit evidence for high-velocity wind components present a stronger signature of the infrared excess, suggesting a causal connection between QSO reddening and the presence of hot dust distributions in QSO winds. We propose that dusty winds at nuclear scales are potentially the physical ingredient responsible for the optical colours in red QSOs, as well as a key parameter for the regulation of accretion material in the nucleus.

show abstract

Fundamental differences in the radio properties of red and blue quasars: insight from the LOFAR Two-metre Sky Survey (LoTSS)

Cited by 39 publications

References 61 publications

Evidence for Radio Loud to Radio Quiet Evolution from Red and Blue Quasars

Evidence for Radio Loud to Radio Quiet Evolution from Red and Blue Quasars

What is the origin of the stacked radio emission in radio-undetected quasars?

The multiwavelength properties of red QSOs: Evidence for dusty winds as the origin of QSO reddening

Contact Info

Product

Resources

About