2021
DOI: 10.1051/0004-6361/202141376
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Maximum accretion rate of supermassive stars

Abstract: Context. The formation of the most massive quasars observed at high redshifts requires extreme inflows of gas down to the length scales of the central compact object. Aims. Here we estimate the maximum inflow rate allowed by gravity down to the surface of supermassive stars, the possible progenitors of these supermassive black holes. Methods. We use the continuity equation and the assumption of spherical symmetry and free fall to derive the maximum allowed inflow rates for various density profiles. We apply ou… Show more

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Cited by 15 publications
(11 citation statements)
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“…The argument in Mayer et al (2010) and Mayer et al (2015) (hereafter MI and MII, respectively) is that SMDs represent an optimal environment for the rapid formation of an SMBH, either through an intermediate supermassive star (SMS) phase (see, e.g. Haemmerlé et al 2020Haemmerlé et al , 2021, or directly via the collapse of a general relativistic (GR)-unstable region. The advantages of the merger-driven scenario are that the formation of SMDs does not require any specific restrictions on thermodynamical conditions of the gas, nor any specific angular momentum loss mechanism other than the ones provided by the hydrodynamics of galaxy mergers.…”
Section: Introductionmentioning
confidence: 99%
“…The argument in Mayer et al (2010) and Mayer et al (2015) (hereafter MI and MII, respectively) is that SMDs represent an optimal environment for the rapid formation of an SMBH, either through an intermediate supermassive star (SMS) phase (see, e.g. Haemmerlé et al 2020Haemmerlé et al , 2021, or directly via the collapse of a general relativistic (GR)-unstable region. The advantages of the merger-driven scenario are that the formation of SMDs does not require any specific restrictions on thermodynamical conditions of the gas, nor any specific angular momentum loss mechanism other than the ones provided by the hydrodynamics of galaxy mergers.…”
Section: Introductionmentioning
confidence: 99%
“…The resulting accumulation of billions of solar masses of gas in a nuclear region less than a parsec in size could either induce the formation of a very large SMS, and hence a massive BH seed by direct collapse, or even directly form a large MBH via the radial general-relativistic instability of a supermassive protostellar precursor. Recent models show that an accreting SMS, owing to the much higher accretion rates occurring in the merger-driven scenario, can grow in mass much more than in the atomic cooling halo case, namely to > 10 7 M in absence of rotation, before collapsing into an MBH seed (Haemmerlé et al, 2021).…”
Section: Mbh Seeds: Formation Mechanismsmentioning
confidence: 99%
“…Conventional star formation involves the collapse of diffuse gas to dense, accreting cores, involving a vast range of temperatures and physical scales. Determining the stellar mass distribution from a collapsing cloud is a non-trivial problem given that complexities in opacity, radiative processes, rotation, and magnetic fields are all critical for determining the resulting stellar masses (Larson 1969;Penston 1969;Stahler & Palla 2004), particularly in regimes of high accretion rates that lead to supermassive stars (Haemmerlé et al 2021;Hosokawa 2019).…”
Section: Astrophysical Rationalementioning
confidence: 99%
“…Such cores collapse rapidly due to the gas conditions, as we will show, experiencing high accretion rates. Certain conditions lead to the formation of supermassive stars (SMSs), for which there are greater uncertainties in the final stellar masses and structure (Hosokawa et al 2013) and subsequent evolution (Haemmerlé et al 2021). Critically, the formation and subsequent evolution of AGNstars does not occur in isolation: gas from the disc may feed the protostellar envelopes and exert torques.…”
Section: Astrophysical Rationalementioning
confidence: 99%