On the Formation and Interaction of Multiple Supermassive Stars in Cosmological Flows

Tyrone E. Woods; Samuel Patrick; Daniel J. Whalen; Alexander Heger

doi:10.3847/1538-4357/ad054a

On the Formation and Interaction of Multiple Supermassive Stars in Cosmological Flows

Tyrone E. Woods, Samuel Patrick, Daniel J. Whalen, Alexander Heger

School of Physics and Astronomy

Research output: Contribution to journal › Article › Research › peer-review

9 Citations (Scopus)

Abstract

Supermassive primordial stars with masses exceeding ∼10⁵ M _⊙ that form in atomically cooled halos are the leading candidates for the origin of high-redshift quasars at z > 6. Recent numerical simulations, however, find that multiple accretion disks can form within a halo, each of which can potentially host a supermassive star. We investigate the formation and evolution of secondary supermassive stars in atomically cooled halos, including strong variations in their accretion histories driven by gravitational interactions between their disks and those surrounding the primary supermassive stars in each halo. We find that all secondary disks produce long-lived supermassive stars under sustained rapid accretion. We also find, however, that the majority of secondary supermassive stars do undergo at least one protracted quiescent accretion phase, during which time they thermally relax and may become powerful sources of ionizing feedback. In many halos, the two satellite disks collide, suggesting that the two stars can come into close proximity. This may induce additional mass exchange between them, leading to a great diversity of possible outcomes. These range from coevolution as main-sequence stars to main sequence—black hole pairs and black hole—black hole mergers. We discuss the likely outcome for these binary interactions based on the evolutionary state of both supermassive stars at the end of our simulations, as well as prospects for their future detection by current and next-generation facilities.

Original language	English
Article number	59
Number of pages	8
Journal	The Astrophysical Journal
Volume	960
Issue number	1
DOIs	https://doi.org/10.3847/1538-4357/ad054a
Publication status	Published - 1 Jan 2024

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10.3847/1538-4357/ad054aLicence: CC BY

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title = "On the Formation and Interaction of Multiple Supermassive Stars in Cosmological Flows",

abstract = "Supermassive primordial stars with masses exceeding ∼105 M ⊙ that form in atomically cooled halos are the leading candidates for the origin of high-redshift quasars at z > 6. Recent numerical simulations, however, find that multiple accretion disks can form within a halo, each of which can potentially host a supermassive star. We investigate the formation and evolution of secondary supermassive stars in atomically cooled halos, including strong variations in their accretion histories driven by gravitational interactions between their disks and those surrounding the primary supermassive stars in each halo. We find that all secondary disks produce long-lived supermassive stars under sustained rapid accretion. We also find, however, that the majority of secondary supermassive stars do undergo at least one protracted quiescent accretion phase, during which time they thermally relax and may become powerful sources of ionizing feedback. In many halos, the two satellite disks collide, suggesting that the two stars can come into close proximity. This may induce additional mass exchange between them, leading to a great diversity of possible outcomes. These range from coevolution as main-sequence stars to main sequence—black hole pairs and black hole—black hole mergers. We discuss the likely outcome for these binary interactions based on the evolutionary state of both supermassive stars at the end of our simulations, as well as prospects for their future detection by current and next-generation facilities.",

author = "Woods, \{Tyrone E.\} and Samuel Patrick and Whalen, \{Daniel J.\} and Alexander Heger",

note = "Funding Information: T.E.W. acknowledges support from the National Research Council Canada{\textquoteright}s Plaskett Fellowship. S.P. was supported by STFC grant ST/N504245/1, and D.J.W. was supported by the Ida Pfeiffer Professorship at the Institute of Astrophysics at the University of Vienna. A.H. was supported by the Australian Research Council (ARC) Centre of Excellence (CoE) for Gravitational Wave Discovery (OzGrav) through project No. CE170100004, by the ARC CoE for All Sky Astrophysics in 3 Dimensions (ASTRO 3D) through project No. CE170100013, and by the National Science Foundation under grant No. PHY-1430152 (JINA Center for the Evolution of the Elements, JINA-CEE). Publisher Copyright: {\textcopyright} 2023. The Author(s). Published by the American Astronomical Society.",

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AU - Heger, Alexander

N1 - Funding Information: T.E.W. acknowledges support from the National Research Council Canada’s Plaskett Fellowship. S.P. was supported by STFC grant ST/N504245/1, and D.J.W. was supported by the Ida Pfeiffer Professorship at the Institute of Astrophysics at the University of Vienna. A.H. was supported by the Australian Research Council (ARC) Centre of Excellence (CoE) for Gravitational Wave Discovery (OzGrav) through project No. CE170100004, by the ARC CoE for All Sky Astrophysics in 3 Dimensions (ASTRO 3D) through project No. CE170100013, and by the National Science Foundation under grant No. PHY-1430152 (JINA Center for the Evolution of the Elements, JINA-CEE). Publisher Copyright: © 2023. The Author(s). Published by the American Astronomical Society.

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N2 - Supermassive primordial stars with masses exceeding ∼105 M ⊙ that form in atomically cooled halos are the leading candidates for the origin of high-redshift quasars at z > 6. Recent numerical simulations, however, find that multiple accretion disks can form within a halo, each of which can potentially host a supermassive star. We investigate the formation and evolution of secondary supermassive stars in atomically cooled halos, including strong variations in their accretion histories driven by gravitational interactions between their disks and those surrounding the primary supermassive stars in each halo. We find that all secondary disks produce long-lived supermassive stars under sustained rapid accretion. We also find, however, that the majority of secondary supermassive stars do undergo at least one protracted quiescent accretion phase, during which time they thermally relax and may become powerful sources of ionizing feedback. In many halos, the two satellite disks collide, suggesting that the two stars can come into close proximity. This may induce additional mass exchange between them, leading to a great diversity of possible outcomes. These range from coevolution as main-sequence stars to main sequence—black hole pairs and black hole—black hole mergers. We discuss the likely outcome for these binary interactions based on the evolutionary state of both supermassive stars at the end of our simulations, as well as prospects for their future detection by current and next-generation facilities.

AB - Supermassive primordial stars with masses exceeding ∼105 M ⊙ that form in atomically cooled halos are the leading candidates for the origin of high-redshift quasars at z > 6. Recent numerical simulations, however, find that multiple accretion disks can form within a halo, each of which can potentially host a supermassive star. We investigate the formation and evolution of secondary supermassive stars in atomically cooled halos, including strong variations in their accretion histories driven by gravitational interactions between their disks and those surrounding the primary supermassive stars in each halo. We find that all secondary disks produce long-lived supermassive stars under sustained rapid accretion. We also find, however, that the majority of secondary supermassive stars do undergo at least one protracted quiescent accretion phase, during which time they thermally relax and may become powerful sources of ionizing feedback. In many halos, the two satellite disks collide, suggesting that the two stars can come into close proximity. This may induce additional mass exchange between them, leading to a great diversity of possible outcomes. These range from coevolution as main-sequence stars to main sequence—black hole pairs and black hole—black hole mergers. We discuss the likely outcome for these binary interactions based on the evolutionary state of both supermassive stars at the end of our simulations, as well as prospects for their future detection by current and next-generation facilities.

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JO - The Astrophysical Journal

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ER -

On the Formation and Interaction of Multiple Supermassive Stars in Cosmological Flows

Abstract

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ARC Centre of Excellence for All Sky Astrophysics in 3 Dimensions

ARC Centre of Excellence for Gravitational Wave Discovery

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On the Formation and Interaction of Multiple Supermassive Stars in Cosmological Flows

Abstract

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ARC Centre of Excellence for All Sky Astrophysics in 3 Dimensions

ARC Centre of Excellence for Gravitational Wave Discovery

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