2018
DOI: 10.3847/2041-8213/aaa462
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On the Rotation of Supermassive Stars

Abstract: Supermassive stars born from pristine gas in atomically-cooled haloes are thought to be the progenitors of supermassive black holes at high redshifts. However, the way they accrete their mass is still an unsolved problem. In particular, for accretion to proceed, a large amount of angular momentum has to be extracted from the collapsing gas. Here, we investigate the constraints stellar evolution imposes on this angular momentum problem. We present an evolution model of a supermassive Population III star includi… Show more

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Cited by 59 publications
(90 citation statements)
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References 63 publications
(92 reference statements)
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“…Models 2 and 4 give consistent results, which are the position dependent accretion models where a dominant object is formed in the core. For the other models we observe a statistical difference due to the more conservative radii of Haemmerlé et al (2017). This difference does not change the conclusion that a single massive object is formed due to a high collision rate.…”
Section: Variation Of Input Parametersmentioning
confidence: 61%
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“…Models 2 and 4 give consistent results, which are the position dependent accretion models where a dominant object is formed in the core. For the other models we observe a statistical difference due to the more conservative radii of Haemmerlé et al (2017). This difference does not change the conclusion that a single massive object is formed due to a high collision rate.…”
Section: Variation Of Input Parametersmentioning
confidence: 61%
“…2). For the higher accretion rates, the models of Haemmerlé et al (2017) produce somewhat smaller radii, but they show the same behaviour at large masses. We use both models to test the sensitivity of the formation of massive objects to the underlying mass-radius parametrization.…”
Section: Mass-radius Evolutionmentioning
confidence: 78%
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