Probing the black hole merger history in clusters using stellar tidal disruptions

Samsing, Johan; Venumadhav, Tejaswi; Dai, Liang; Martínez, I. Jiménez; Batta, Aldo; Lopez, Martin; Ramírez-Ruiz, E.; Kremer, Kyle

doi:10.1103/physrevd.100.043009

Cited by 28 publications

(25 citation statements)

References 144 publications

(180 reference statements)

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“…2) x 10 -9 yr -1 , compatible with the value expected for TDEs triggered by BH binaries 41,42 . The 90% of disrupted stars have a mass < 0.5 M☉, thus possibly representing white dwarfs or low-mass main sequence stars.…”

Section: Resultssupporting

confidence: 83%

Dissecting the properties of neutron star–black hole mergers originating in dense star clusters

Sedda

2020

Commun Phys

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The detection of gravitational waves emitted during a neutron star -black hole merger and the associated electromagnetic counterpart will provide a wealth of information about stellar evolution nuclear matter, and General Relativity. While the theoretical framework about neutron star -black hole binaries formed in isolation is well established, the picture is loosely constrained for those forming via dynamical interactions. Here, we use N-body simulations to show that mergers forming in globular and nuclear clusters could display distinctive marks compared to isolated mergers, namely larger masses, heavier black holes, and the tendency to have no associated electromagnetic counterpart. These features could represent a useful tool to interpreting forthcoming observations. In the Local Universe, gravitational waves emitted from dynamical mergers could be unravelled by detectors sensitive in the decihertz frequency band, while those occurring at the distance range of Andromeda and the Virgo Cluster could be accessible to lower-frequency detectors like LISA.The third observational campaign, O3, operated by the LIGO-Virgo Collaboration (LVC) will enlarge the family of gravitational wave (GW) sources, currently comprised of 11 confirmed black hole (BH) binary and 1 neutron star (NS) binary mergers 1 . The loot of observations accumulated during O3 will hopefully include the first BH binary with component masses in the so-called upper mass-gap, i.e. 50 − 150 M☉, and the first NS-BH merger. In fact, as reported in the gravitational-wave candidate event database (GraceDB, https://gracedb.ligo.org/), both events might have been already recorded. The observation of an NS-BH merger represents a crucial cornerstone in both GW astronomy and stellar evolution and dynamics. The GW signal emitted by this type of sources encodes information about the mass ratio of the binary, the BH spin, the NS compactness and equation of state 2-4 . The next generation of GW detectors will allow us to chase these objects up to the dawn of Universe 5 , offering us the unique chance to follow them from the inspiraling phase to the merger. The formation of an accretion disc during the merger could trigger a kilonova event 6 and power a short Gamma-ray burst (sGRB) 7 , making NS-BH mergers promising multimessenger sources. The coincident observation of GWs and a kilonova 8 , the detection of peculiar precession in the jets produced during the sGRB 9 , or the anisotropic emission of ejected matter 10 are some of the proposed signatures of a putative NS-BH electromagnetic (EM) counterpart. The properties of the EM emission depend on the binary properties close to the merger. A high eccentricity, for instance, can affect the amount of mass ejected, the mass accreted onto the BH and the angular momentum transferred 11 . The actual development of an EM counterpart is expected to depend likely on the mass ratio, the BH spin, and the NS equation of state 2-4,10-12 . For mass ratios smaller than ≃1/3 − 1/4, the NS undergoes tidal disruption inside the BH's ...

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Section: Resultssupporting

confidence: 83%

Dissecting the properties of neutron star–black hole mergers originating in dense star clusters

Sedda

2020

Commun Phys

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“…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%

“…Note that this same scaling is found in the equal mass case (e.g., Samsing et al 2017;Samsing 2018). Here, we take P TD = 2R TD /a BBH as in Samsing et al (2019). We can then rewrite Equation (9) as…”

Section: Binary-mediated Tdesmentioning

confidence: 99%

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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“…We obtain the distribution of cluster formation times from the semi-analytical galaxy formation model of El-Badry et al [80]. The same model has also been used in recent work [e.g., 31,81], allowing a direct comparison of our results to literature. El-Badry et al [80] describe the process of GC formation as resulting from star formation activity in the high-density disks of gas-rich galaxies.…”

Section: Cluster Formation and Initial Propertiesmentioning

confidence: 99%

Merger rate of black hole binaries from globular clusters: Theoretical error bars and comparison to gravitational wave data from GWTC-2

Antonini

Gieles

2020

Phys. Rev. D

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Probing the black hole merger history in clusters using stellar tidal disruptions

Cited by 28 publications

References 144 publications

Dissecting the properties of neutron star–black hole mergers originating in dense star clusters

Dissecting the properties of neutron star–black hole mergers originating in dense star clusters

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

Merger rate of black hole binaries from globular clusters: Theoretical error bars and comparison to gravitational wave data from GWTC-2

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