Populating the Upper Black Hole Mass Gap through Stellar Collisions in Young Star Clusters

Kremer, Kyle; Spera, M.; Becker, Devin; Chatterjee, Sourav; Carlo, Ugo N. Di; Fragione, Giacomo; Rodriguez, Carl L.; Ye, Claire S.; Rasio, Frederic A.

doi:10.3847/1538-4357/abb945

Cited by 138 publications

(119 citation statements)

References 201 publications

(268 reference statements)

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“…In the case of extremely efficient energy release in the form of a jet, a bright X-ray or γray flare may result with the overall phenomenology possibly resembling ultra-long gamma-ray bursts (Perets et al 2016). These TDEs are expected to occur in GCs at rates of roughly 3-10 Gpc −3 yr −1 (Perets et al 2016;Lopez et al 2020;Kremer et al 2019c) and at similar rates in both nuclear star clusters (Fragione et al 2020) and in stellar triples under the influence of Lidov-Kozai oscillations (Fragione et al 2019).…”

Section: Introductionmentioning

confidence: 90%

“…BH-star encounters are expected to play a crucial role in the formation of both accreting and detached BH binaries (e.g., Ivanova et al 2010Ivanova et al , 2017Giesler et al 2018;Kremer et al 2018a) with properties similar to the BH candidates detected to date in Milky Way GCs (e.g., Kremer et al 2019a). Additionally, such dynamical encounters may occasionally cause a star to cross a BH within its tidal disruption radius, leading to a tidal disruption of the star (Perets et al 2016;Lopez et al 2020;Kremer et al 2019bKremer et al , 2019cSamsing et al 2019;Fragione et al 2020). These stellar-mass BH tidal disruption events (TDEs) may occur during close encounters of pairs of single stars (i.e., single-single interactions) and also during small-N (typically three-or four-body) resonant encounters that occur through binary-mediated dynamical interactions (e.g., Fregeau & Rasio 2007).…”

Section: Introductionmentioning

confidence: 93%

“…In reality, especially if the TDE occurs during a multi-body resonant encounter, TDEs may affect the hydrodynamic evolution of their dynamical encounters. These more complex effects are well beyond the computational scope of an N-body code like CMC, but see e.g., Lopez et al (2020) for a discussion. We apply this TDE prescription only for BH-star interactions.…”

Section: N-body Models Of Young Clustersmentioning

confidence: 99%

“…For close encounters of star-star pairs, we allow the stars to interact only in the direct collision limit: we assume a sticky sphere collision (i.e., zero mass loss) occurs if r p < R 1 + R 2 , where R 1 and R 2 are the stellar radii. See Kremer et al (2020a) for further details of our treatment of star-star collisions. We record TDEs/collisions that occur during both single-single encounters and binary-mediated dynamical encounters that are integrated directly using Fewbody.…”

Section: N-body Models Of Young Clustersmentioning

confidence: 99%

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Fast Optical Transients from Stellar-mass Black Hole Tidal Disruption Events in Young Star Clusters

Kremer

Piro

et al. 2021

ApJ

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Observational evidence suggests that the majority of stars may have been born in stellar clusters or associations. Within these dense environments, dynamical interactions lead to high rates of close stellar encounters. A variety of recent observational and theoretical indications suggest stellar-mass black holes may be present and play an active dynamical role in stellar clusters of all masses. In this study, we explore the tidal disruption of main-sequence stars by stellar-mass black holes in young star clusters. We compute a suite of over 3000 independent N-body simulations that cover a range of cluster mass, metallicity, and half-mass radii. We find stellar-mass black hole tidal disruption events (TDEs) occur at an overall rate of up to roughly 200 Gpc−3 yr−1 in young stellar clusters in the local universe. These TDEs are expected to have several characteristic features, namely, fast rise times of order a day, peak X-ray luminosities of at least 1044 erg s−1, and bright optical luminosities (roughly 1041–1044 erg s−1) associated with reprocessing by a disk wind. In particular, we show these events share many features in common with the emerging class of Fast Blue Optical Transients.

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Section: Introductionmentioning

confidence: 90%

Section: Introductionmentioning

confidence: 93%

Section: N-body Models Of Young Clustersmentioning

confidence: 99%

Section: N-body Models Of Young Clustersmentioning

confidence: 99%

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Fast Optical Transients from Stellar-mass Black Hole Tidal Disruption Events in Young Star Clusters

Kremer

Piro

et al. 2021

ApJ

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“…Second, for initial N held constant, clusters with top-heavy IMFs also have greater total mass and higher collision rates in their densely populated cores. This collision rate enhancement is obvious in Table 1, column 7, listing the number of mass gap BBH merger components formed from the stellar product of collisions (e.g., Di Carlo et al 2020;Kremer et al 2020c). While the column only lists collisionally formed merger components in the mass gap, the overall collision rate scales similarly with decreasing α 3 .…”

Section: Bh and Bbh Merger Massesmentioning

confidence: 96%

Black Hole Mergers from Star Clusters with Top-heavy Initial Mass Functions

Weatherford

Fragione

Kremer

et al. 2021

ApJL

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Recent observations of globular clusters (GCs) provide evidence that the stellar initial mass function (IMF) may not be universal, suggesting specifically that the IMF grows increasingly top-heavy with decreasing metallicity and increasing gas density. Noncanonical IMFs can greatly affect the evolution of GCs, mainly because the high end determines how many black holes (BHs) form. Here we compute a new set of GC models, varying the IMF within observational uncertainties. We find that GCs with top-heavy IMFs lose most of their mass within a few gigayears through stellar winds and tidal stripping. Heating of the cluster through BH mass segregation greatly enhances this process. We show that, as they approach complete dissolution, GCs with top-heavy IMFs can evolve into "dark clusters" consisting of mostly BHs by mass. In addition to producing more BHs, GCs with top-heavy IMFs also produce many more binary BH (BBH) mergers. Even though these clusters are short-lived, mergers of ejected BBHs continue at a rate comparable to, or greater than, what is found for long-lived GCs with canonical IMFs. Therefore, these clusters, though they are no longer visible today, could still contribute significantly to the local BBH merger rate detectable by LIGO/Virgo, especially for sources with higher component masses well into the BH mass gap. We also report that one of our GC models with a top-heavy IMF produces dozens of intermediatemass black holes (IMBHs) with masses, including one with. Ultimately, additional gravitational wave observations will provide strong constraints on the stellar IMF in old GCs and the formation of IMBHs at high redshift.

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Formation Channels of Single and Binary Stellar-Mass Black Holes

Mapelli

2021

Handbook of Gravitational Wave Astronomy

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Populating the Upper Black Hole Mass Gap through Stellar Collisions in Young Star Clusters

Cited by 138 publications

References 201 publications

Fast Optical Transients from Stellar-mass Black Hole Tidal Disruption Events in Young Star Clusters

Fast Optical Transients from Stellar-mass Black Hole Tidal Disruption Events in Young Star Clusters

Black Hole Mergers from Star Clusters with Top-heavy Initial Mass Functions

Formation Channels of Single and Binary Stellar-Mass Black Holes

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