From the first stars to the first black holes

Valiante, Rosa; Schneider, Raffaella; Volonteri, Marta; Omukai, Kazuyuki

doi:10.1093/mnras/stw225

Cited by 145 publications

(306 citation statements)

References 132 publications

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“…Dijkstra et al 2008Dijkstra et al , 2014 to 10 −6 -10 −4 Mpc −3 (e.g. Agarwal et al 2012;Chon et al 2016;Habouzit et al 2016;Valiante et al 2016). Although those seeds can account for rare BHs in the high-z universe, they fail to be as abundant as all the SMBHs ubiquitously residing in massive galaxies, ∼ 0.01-0.1 Mpc −3 (Aller & Richstone 2002; Davis et al 2014).…”

Section: Discussionmentioning

confidence: 99%

Supermassive star formation via super competitive accretion in slightly metal-enriched clouds

Chon

Omukai

2020

Monthly Notices of the Royal Astronomical Society

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Direct collapse black hole (DCBH) formation with mass 10 5 M is a promising scenario for the origin of high-redshift supermassive black holes. It has usually been supposed that the DCBH can only form in the primordial gas since the metal enrichment enhances the cooling ability and causes the fragmentation into smaller pieces. What actually happens in such an environment, however, has not been explored in detail. Here, we study the impact of the metal enrichment on the clouds, conducting hydrodynamical simulations to follow the cloud evolution in cases with different degree of the metal enrichment Z/Z = 10 −6 − 10 −3 . Below Z/Z = 10 −6 , metallicity has no effect and supermassive stars form along with a small number of low-mass stars. With more metallicity Z/Z > ∼ 5 × 10 −6 , although the dust cooling indeed promotes fragmentation of the cloud core and produces about a few thousand low-mass stars, the accreting flow preferentially feeds the gas to the central massive stars, which grows supermassive as in the primordial case. We term this formation mode as the super competitive accretion, where only the central few stars grow supermassive while a large number of other stars are competing for the gas reservoir. Once the metallicity exceeds 10 −3 Z and metal-line cooling becomes operative, the central star cannot grow supermassive due to lowered accretion rate. Supermassive star formation by the super competitive accretion opens up a new window for seed BHs, which relaxes the condition on metallicity and enhances the seed BH abundance.

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Section: Discussionmentioning

confidence: 99%

Supermassive star formation via super competitive accretion in slightly metal-enriched clouds

Chon

Omukai

2020

Monthly Notices of the Royal Astronomical Society

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“…While the black hole seeds from Population III stars are expected to be relatively small (∼100 M e ; e.g., Valiante et al 2016), direct collapse of massive clouds can lead to the formation of more massive seeds ( 10 10 4 6 -M e ; for a review see Volonteri 2010). In general, the time in which a black hole of mass M BH,f is grown from an initial seed M BH,seed , assuming that it accretes with a constant Eddington ratio for all the time, can be written as Figure 9.…”

Section: Black Hole Seedsmentioning

confidence: 99%

“…The current preferred models include the formation of black hole seeds from the direct collapse of massive gaseous reservoirs (e.g., Haehnelt & Rees 1993;Latif & Schleicher 2015), the collapse of Population III stars (e.g., Bond et al 1984;Alvarez et al 2009;Valiante et al 2016), the co-action of dynamical processes, gas collapse and star formation (e.g., Devecchi & Volonteri 2009), or the rapid growth of stellar-mass seeds via episodes of super-Eddington, radiatively inefficient accretion (e.g., Alexander & Natarajan 2014;Madau et al 2014;Pacucci et al 2015;Lupi et al 2016;Pezzulli et al 2016;Volonteri et al 2016;Begelman & Volonteri 2017 , assuming accretion at the Eddington limit and an efficiency of 10%; Volonteri & Rees 2005). For instance, in the seemingly short redshift range z 6.0 6.5 -, corresponding to ∼90 Myr, a black hole can grow by a factor of 6.…”

Section: Introductionmentioning

confidence: 99%

Physical Properties of 15 Quasars at z ≳ 6.5

Mazzucchelli

Bañados

Venemans

et al. 2017

ApJ

319

444

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Quasars are galaxies hosting accreting supermassive black holes; due to their brightness, they are unique probes of the early universe. To date, only a few quasars have been reported at (<800 Myr after the big bang). In this work, we present six additional quasars discovered using the Pan-STARRS1 survey. We use a sample of 15 quasars to perform a homogeneous and comprehensive analysis of this highest-redshift quasar population. We report four main results: (1) the majority of quasars show large blueshifts of the broad C iv λ1549 emission line compared to the systemic redshift of the quasars, with a median value ∼3× higher than a quasar sample at ; (2) we estimate the quasars’ black hole masses ( (0.3–5) × 109 M ⊙) via modeling of the Mg ii λ2798 emission line and rest-frame UV continuum and find that quasars at high redshift accrete their material (with ) at a rate comparable to a luminosity-matched sample at lower redshift, albeit with significant scatter (0.4 dex); (3) we recover no evolution of the Fe ii/Mg ii abundance ratio with cosmic time; and (4) we derive near-zone sizes and, together with measurements for quasars from recent work, confirm a shallow evolution of the decreasing quasar near-zone sizes with redshift. Finally, we present new millimeter observations of the [C ii] 158 μm emission line and underlying dust continuum from NOEMA for four quasars and provide new accurate redshifts and [C ii]/infrared luminosity estimates. The analysis presented here shows the large range of properties of the most distant quasars.

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“…In the second method, a seed BH of a fixed mass is placed immediately after a galaxy forms: 10 2 M⊙ (Menci et al 2003), 10 3 M⊙ (Fontanot et al 2015), or 10 5 M⊙ . For a deeper understanding of seed BHs from SA models, Pezzulli et al (2016) and Valiante et al (2016) focus on BH growth only in early universe (z 5) and suggest that 100 M⊙ seed BHs at z 23 accretes gas via major mergers at super-Eddington rates, forming 10…”

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confidence: 99%

Theoretical re-evaluations of the black hole mass–bulge mass relation – I. Effect of seed black hole mass

Shirakata

Kawaguchi

Okamoto

et al. 2016

Mon. Not. R. Astron. Soc.

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We explore the effect of varying the mass of the seed black hole on the resulting black hole mass -bulge mass relation at z ∼ 0, using a semi-analytic model of galaxy formation combined with large cosmological N -body simulations. We constrain our model by requiring the observed properties of galaxies at z ∼ 0 are reproduced. In keeping with previous semi-analytic models, we place a seed black hole immediately after a galaxy forms. When the mass of the seed is set at 10 5 M ⊙ , we find that the model results become inconsistent with recent observational results of the black hole mass -bulge mass relation for dwarf galaxies. In particular, the model predicts that bulges with ∼ 10 9 M ⊙ harbour larger black holes than observed. On the other hand, when we employ seed black holes with 10 3 M ⊙ , or randomly select their mass within a 10 3−5 M ⊙ range, the resulting relation is consistent with observation estimates, including the observed dispersion. We find that to obtain stronger constraints on the mass of seed black holes, observations of less massive bulges at z ∼ 0 are a more powerful comparison than the relations at higher redshifts.

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From the first stars to the first black holes

Cited by 145 publications

References 132 publications

Supermassive star formation via super competitive accretion in slightly metal-enriched clouds

Supermassive star formation via super competitive accretion in slightly metal-enriched clouds

Physical Properties of 15 Quasars at z ≳ 6.5

Theoretical re-evaluations of the black hole mass–bulge mass relation – I. Effect of seed black hole mass

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