Supermassive black holes in cosmological simulations I: <i>M</i>BH − <i>M</i>⋆ relation and black hole mass function

Habouzit, Mélanie; Li, Yuan; Somerville, Rachel S.; Genel, Shy; Pillepich, Annalisa; Volonteri, Marta; Davé, Romeel; Rosas-Guevara, Yetli; McAlpine, Stuart; Peirani, Sébastien; Hernquist, Lars; Anglés-Alcázar, Daniel; Reines, Amy E.; Bower, Richard G.; Dubois, Yohan; Nelson, Dylan; Pichon, Christophe; Vogelsberger, Mark

doi:10.1093/mnras/stab496

Cited by 102 publications

(91 citation statements)

References 166 publications

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“…Further observations of galaxies hosting less massive SMBHs are necessary to confirm this picture statistically. As the coevolution relation is the end product of the complex growth of galaxies and SMBHs, a statistical measurement of this relation at the early universe (see also, e.g., Suh et al 2020;Setoguchi et al 2021) would help constrain the relative cosmological importance of various feeding and feedback processes (Habouzit et al 2021). We also need high-resolution observations sensitive to detailed dynamics, as well as wide-area deep observations sensitive to the surrounding environments, to reveal the driving mechanism of the rapid growth of galaxies and SMBHs in the early universe.…”

Section: Early Coevolution At Z ∼mentioning

confidence: 99%

Subaru High-z Exploration of Low-luminosity Quasars (SHELLQs). XIII. Large-scale Feedback and Star Formation in a Low-luminosity Quasar at z = 7.07 on the Local Black Hole to Host Mass Relation

Izumi

Matsuoka

Fujimoto³

et al. 2021

ApJ

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We present Atacama Large Millimeter/submillimeter Array [C II] 158 μm line and underlying far-infrared (FIR) continuum emission observations (0 70 × 0 56 resolution) toward HSC J124353.93+010038.5 (J1243+0100) at z = 7.07, the only low-luminosity (M 1450 > −25 mag) quasar currently known at z > 7. The FIR continuum is bright (1.52 mJy) and resolved with a total luminosity of L FIR = 3.5 × 10 12 L e . The spatially extended component is responsible for ∼40% of the emission. The area-integrated [C II] spectrum shows a broad wing (FWHM = 997 km s −1 , L [C II] = 1.2 × 10 9 L e ), as well as a bright core (FWHM = 235 km s −1 , L [C II] = 1.9 × 10 9 L e ). This wing is the first detection of a galactic-scale quasar-driven outflow (atomic outflow rate >447 M e yr −1 ) at z > 7. The estimated large mass-loading factor of the total outflow (e.g., 9 relative to the [C II]-based star formation rate) suggests that this outflow will soon quench the star formation of the host. The core gas dynamics are governed by rotation, with a rotation curve suggestive of a compact bulge (∼3.3 × 10 10 M e ), although it is not yet spatially resolved. Finally, we found that J1243+0100 has a black hole mass-to-dynamical mass (and -to-bulge mass) ratio of ∼0.4% (∼1%), consistent with the local value within the uncertainties. Our results therefore suggest that the black hole-host coevolution relation is already in place at z ∼ 7 for this object.Unified Astronomy Thesaurus concepts: Quasars (1319); AGN host galaxies (2017); Active galaxies (17); Interstellar medium (847); Submillimeter astronomy (1647); High-redshift galaxies (734); Galaxy evolution (594)

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Section: Early Coevolution At Z ∼mentioning

confidence: 99%

Subaru High-z Exploration of Low-luminosity Quasars (SHELLQs). XIII. Large-scale Feedback and Star Formation in a Low-luminosity Quasar at z = 7.07 on the Local Black Hole to Host Mass Relation

Izumi

Matsuoka

Fujimoto³

et al. 2021

ApJ

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“…In order to better probe the exact epoch and search volume of our observational QSO sample, we carried out a census of bright AGN pairs at z = 6 in the Illustris-TNG300 (hereafter TNG300) and L-Galaxies 2020 galaxy evolution models. TNG300 (Pillepich et al 2018;Springel et al 2018;Naiman et al 2018;Marinacci et al 2018;Nelson et al 2018) is a magneto-hydrodynamical simulation run in a (205 h −1 Mpc) 3 box, using a Bondi-Hoyle-Lyttleton BH accretion model with no boost factor but an assumed BH seed mass of 8 × 10 5 M (see Habouzit et al 2021). L-Galaxies 2020 (Henriques et al 2020) is a semi-analytic model run on the larger (480 h −1 Mpc) 3 Millennium-I box (Springel et al 2005), but with a more simplified phenomenological model of quasar-and radio-mode BH accretion and no BH seed mass (see Croton et al 2006).…”

Section: Comparison To Simulationsmentioning

confidence: 99%

“…Currently, cosmologicalscale simulations typically either focus on quasar properties below z ∼ 5 due to improved statistics (e.g., DeGraf & Sijacki 2017;Bhowmick et al 2019;Habouzit et al 2021) or above z ∼ 7 due to reduced computational limitations (e.g., DiMatteo et al 2017;Tenneti et al 2019;Marshall et al 2020). Zoom-in simulations of halos containing QSOs at z ∼ 6−7 have been performed (e.g.,Costa et al 2014;Lupi et al 2019); however, they do not readily provide statistics on large scales.…”

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confidence: 99%

Quasar clustering at redshift 6

Greiner

Bolmer

Yates

et al. 2021

A&A

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Context. Large-scale surveys over the last years have revealed about 300 quasi-stellar objects (QSOs) at redshifts above 6. Follow-up observations have identified surprising properties, such as the very high black hole (BH) masses, spatial correlations with surrounding cold gas of the host galaxy, and high CIV-MgII Velocity shifts. In particular, the discovery of luminous high-redshift quasars suggests that at least some BHs likely have high masses at birth and grow efficiently. Aims. Our aim is to quantify quasar pairs at high redshift for a large sample of objects. This provides a new key constraint on a combination of parameters related to the origin and assembly for the most massive BHs: formation efficiency and clustering, growth efficiency, and the relative contribution of BH mergers. Methods. We observed 116 spectroscopically confirmed QSOs around redshift 6 with the simultaneous seven-channel imager Gamma-ray Burst Optical/Near-infrared Detector in order to search for companions. Applying colour-colour cuts identical to those which led to the spectroscopically confirmed QSOs, we performed Le PHARE fits to the 26 best QSO pair candidates, and obtained spectroscopic observations for 11 of them. Results. We do not find any QSO pair with a companion brighter than M1450(AB) < −26 mag within our 0.1–3.3 h−1 cMpc search radius, in contrast to the serendipitous findings in the redshift range 4–5. However, a small fraction of such pairs at this luminosity and redshift is consistent with indications from present-day cosmological-scale galaxy evolution models. In turn, the incidence of L- and T-type brown dwarfs, which occupy a similar colour space to z ∼ 6 QSOs, is higher than expected, by a factor of 5 and 20, respectively.

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“…Such simulations have been successful at producing galaxies in good agreement with the properties of observed galaxies. Nevertheless, discrepancies among the simulations exist and arise from the use of different galaxy and BH subgrid physics (Habouzit et al 2021). The formation of BHs in these simulations does not follow the theoretical prescriptions of BH formation mechanisms.…”

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confidence: 92%

The black hole population in low-mass galaxies in large-scale cosmological simulations

Haidar,

Habouzit,

Volonteri

et al. 2022

Preprint

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Recent systematic searches for massive black holes (BHs) in local dwarf galaxies led to the discovery of a population of faint Active Galactic Nuclei (AGN). We investigate the agreement of the BH and AGN populations in the Illustris, TNG, Horizon-AGN, EAGLE, and SIMBA simulations with current observational constraints in low-mass galaxies. We find that some of these simulations produce BHs that are too massive, and that the BH occupation fraction at z = 0 is not inherited from the simulation seeding modeling. In simulations, the ability of BHs and their host galaxies to power an AGN depends on the subgrid modeling of the BH and of the galaxy. The fraction of AGN in low-mass galaxies is not used to calibrate the simulations, and thus is a true prediction. AGN fractions at z = 0 span two orders of magnitude at fixed galaxy stellar mass in simulations, similarly to observational constraints, but uncertainties and degeneracies affect both observations and simulations. The agreement is difficult to interpret due to differences in BH masses between simulations and observations, BH occupation fraction affected by numerical choices, and an unknown obscured fraction of AGN. Our work advocates for more thorough comparisons with observations in the low-mass regime to improve the modeling of cosmological simulations, and our understanding of BH and galaxy physics in this regime. The mass of BHs, their ability to efficiently accrete gas, and the AGN occupation fraction in low-mass galaxies have important implications for the build-up of the entire BH and galaxy populations with time.

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Supermassive black holes in cosmological simulations I: MBH − M⋆ relation and black hole mass function

Cited by 102 publications

References 166 publications

Subaru High-z Exploration of Low-luminosity Quasars (SHELLQs). XIII. Large-scale Feedback and Star Formation in a Low-luminosity Quasar at z = 7.07 on the Local Black Hole to Host Mass Relation

Subaru High-z Exploration of Low-luminosity Quasars (SHELLQs). XIII. Large-scale Feedback and Star Formation in a Low-luminosity Quasar at z = 7.07 on the Local Black Hole to Host Mass Relation

Quasar clustering at redshift 6

The black hole population in low-mass galaxies in large-scale cosmological simulations

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