Making a Supermassive Star by Stellar Bombardment

ASTROPHYSICAL JOURNAL American Astronomical Society 892:1 (2020) ARTN 36

Authors:

Hiromichi Tagawa, Zoltan Haiman, Bence Kocsis

Abstract:

Approximately two hundred supermassive black holes (SMBHs) have been discovered within the first $\sim$Gyr after the Big Bang. One pathway for the formation of SMBHs is through the collapse of supermassive stars (SMSs). A possible obstacle to this scenario is that the collapsing gas fragments and forms a cluster of main-sequence stars. Here we raise the possibility that stellar collisions may be sufficiently frequent and energetic to inhibit the contraction of the massive protostar, avoiding strong UV radiation driven outflows, and allowing it to continue growing into an SMS. We investigate this scenario with semianalytic models incorporating star formation, gas accretion, dynamical friction from stars and gas, stellar collisions, and gas ejection. We find that when the collapsing gas fragments at a density of $\lesssim 3\times 10^{10}\,\mathrm{cm^{-3}}$, the central protostar contracts due to infrequent stellar mergers, and in turn photoevaporates the remaining collapsing gas, resulting in the formation of a $\lesssim 10^4~{\rm M_\odot}$ object. On the other hand, when the collapsing gas fragments at higher densities (expected for a metal-poor cloud with $Z\lesssim10^{-5}\,{\rm Z_\odot}$ with suppressed ${\rm H_2}$ abundance) the central protostar avoids contraction and keeps growing via frequent stellar mergers, reaching masses as high as $\sim 10^5-10^6\,{\rm M_\odot}$. We conclude that frequent stellar mergers represent a possible pathway to form massive BHs in the early universe.

Multiwavelength consensus of large-scale linear bias

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 493:1 (2020) 747-764

Authors:

Hengxing Pan, Danail Obreschkow, Cullan Howlett, Claudia del P Lagos, Pascal J Elahi, Carlton Baugh, Violeta Gonzalez-Perez

Cosmic Evolution of Stellar-mass Black Hole Merger Rate in Active Galactic Nuclei

(2020)

Authors:

Y Yang, I Bartos, Z Haiman, B Kocsis, S Márka, H Tagawa

Dust and gas content of high-redshift galaxies hosting obscured AGN in the CDF-S

(2020)

Authors:

Q D'Amato, R Gilli, C Vignali, M Massardi, F Pozzi, G Zamorani, C Circosta, F Vito, J Fritz, G Cresci, V Casasola, F Calura, A Feltre, V Manieri, D Rigopoulou, P Tozzi, C Norman

Formation channels of slowly rotating early-type galaxies

Astronomy and Astrophysics EDP Sciences 635 (2020) A129

Authors:

Davor Krajnovic, Ugur Ural, Harald Kuntschner, Paul Goudfrooij, Michael Wolfe, Michele Cappellari, Roger Davies, Tim P de Zeeuw, Pierre-Alain Duc, Eric Emsellem, Arna Karick, Richard M McDermid, Simona Mei, Thorsten Naab

Abstract:

We study the evidence for a diversity of formation processes in early-type galaxies by presenting the first complete volume-limited sample of slow rotators with both integral-field kinematics from the ATLAS3D Project and high spatial resolution photometry from the Hubble Space Telescope. Analysing the nuclear surface brightness profiles of 12 newly imaged slow rotators, we classify their light profiles as core-less, and place an upper limit to the core size of about 10 pc. Considering the full magnitude and volume-limited ATLAS3D sample, we correlate the presence or lack of cores with stellar kinematics, including the proxy for the stellar angular momentum (λRe) and the velocity dispersion within one half-light radius (σe), stellar mass, stellar age, α-element abundance, and age and metallicity gradients. More than half of the slow rotators have core-less light profiles, and they are all less massive than 1011 M⊙. Core-less slow rotators show evidence for counter-rotating flattened structures, have steeper metallicity gradients, and a larger dispersion of gradient values (Δ[Z/H]¯ = −0.42 ± 0.18) than core slow rotators (Δ[Z/H]¯ = −0.23 ± 0.07). Our results suggest that core and core-less slow rotators have different assembly processes, where the former, as previously discussed, are the relics of massive dissipation-less merging in the presence of central supermassive black holes. Formation processes of core-less slow rotators are consistent with accretion of counter-rotating gas or gas-rich mergers of special orbital configurations, which lower the final net angular momentum of stars, but support star formation. We also highlight core fast rotators as galaxies that share properties of core slow rotators (i.e. cores, ages, σe, and population gradients) and core-less slow rotators (i.e. kinematics, λRe, mass, and larger spread in population gradients). Formation processes similar to those for core-less slow rotators can be invoked to explain the assembly of core fast rotators, with the distinction that these processes form or preserve cores.