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1. Demographics of Hierarchical Black Hole Mergers in Dense Star Clusters

   https://doi.org/10.3847/1538-4357/acd9c9  

   Fragione, Giacomo; Rasio, Frederic A. (July 2023, The Astrophysical Journal)

   Abstract With about one hundred mergers of binary black holes (BBHs) detected via gravitational waves by the LIGO-Virgo-KAGRA (LVK) Collaboration, our understanding of the darkest objects in the universe has taken unparalleled steps forward. While most of the events are expected to consist of black holes (BHs) directly formed from the collapse of massive stars, some may contain the remnants of previous BBH mergers. In the most massive globular clusters and in nuclear star clusters, successive mergers can produce second- (2G) or higher-generation BHs, and even form intermediate-mass BHs (IMBHs). Overall, we predict that up to ∼10%, ∼1%, or ∼0.1% of the BBH mergers have one component being a 2G, 3G, or 4G BH, respectively. Assuming that ∼500 BBH mergers will be detected in O4 by LVK, this means that ∼50, ∼5, or ∼0.5 events, respectively, will involve a 2G, 3G, or 4G BH, if most sources are produced dynamically in dense star clusters. With their distinctive signatures of higher masses and spins, such hierarchical mergers offer an unprecedented opportunity to learn about the BH populations in the densest stellar systems and to shed light on the elusive IMBHs that may form therein. 

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2. Signatures of hierarchical mergers in black hole spin and mass distribution

   https://doi.org/10.1093/mnras/stab2315  

   Tagawa, Hiromichi; Haiman, Zoltán; Bartos, Imre; Kocsis, Bence; Omukai, Kazuyuki (September 2021, Monthly Notices of the Royal Astronomical Society)

   ABSTRACT Recent gravitational wave (GW) observations by LIGO/Virgo show evidence for hierarchical mergers, where the merging BHs are the remnants of previous BH merger events. These events may carry important clues about the astrophysical host environments of the GW sources. In this paper, we present the distributions of the effective spin parameter (χeff), the precession spin parameter (χp), and the chirp mass (mchirp) expected in hierarchical mergers. Under a wide range of assumptions, hierarchical mergers produce (i) a monotonic increase of the average of the typical total spin for merging binaries, which we characterize with $$\scriptstyle{{\bar{\chi }}_\mathrm{typ}\equiv \overline{(\chi _\mathrm{eff}^2+\chi _\mathrm{p}^2)^{1/2}}}$$, up to roughly the maximum mchirp among first-generation (1g) BHs, and (ii) a plateau at $${\bar{\chi }}_\mathrm{typ}\sim 0.6$$ at higher mchirp. We suggest that the maximum mass and typical spin magnitudes for 1g BHs can be estimated from $${\bar{\chi }}_\mathrm{typ}$$ as a function of mchirp. The GW data observed in LIGO/Virgo O1–O3a prefers an increase in $${\bar{\chi }}_\mathrm{typ}$$ at low mchirp, which is consistent with the growth of the BH spin magnitude by hierarchical mergers at ∼2σ confidence. A Bayesian analysis using the χeff, χp, and mchirp distributions suggests that 1g BHs have the maximum mass of ∼15–$$30\, {\rm M}_\odot$$ if the majority of mergers are of high-generation BHs (not among 1g–1g BHs), which is consistent with mergers in active galactic nucleus discs and/or nuclear star clusters, while if mergers mainly originate from globular clusters, 1g BHs are favoured to have non-zero spin magnitudes of ∼0.3. We also forecast that signatures for hierarchical mergers in the $${\bar{\chi }}_\mathrm{typ}$$ distribution can be confidently recovered once the number of GW events increases to ≳ O(100). 

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3. Monte Carlo simulations of black hole mergers in AGN discs: Low χeff mergers and predictions for LIGO

   https://doi.org/10.1093/mnras/staa740  

   McKernan, B; Ford, K E; O’Shaugnessy, R; Wysocki, D (May 2020, Monthly Notices of the Royal Astronomical Society)

   ABSTRACT Accretion discs around supermassive black holes are promising sites for stellar mass black hole mergers detectable with LIGO. Here we present the results of Monte Carlo simulations of black hole mergers within 1-d AGN disc models. For the spin distribution in the disc bulk, key findings are: (1) The distribution of χeff is naturally centred around $$\tilde{\chi }_{\rm eff} \approx 0.0$$, (2) the width of the χeff distribution is narrow for low natal spins. For the mass distribution in the disc bulk, key findings are: (3) mass ratios $$\tilde{q} \sim 0.5\!-\!0.7$$, (4) the maximum merger mass in the bulk is $$\sim 100\!-\!200\, \mathrm{M}_{\odot }$$, (5) $$\sim 1{{\ \rm per\ cent}}$$ of bulk mergers involve BH $$\gt 50\, \mathrm{M}_{\odot }$$ with (6) $$\simeq 80{{\ \rm per\ cent}}$$ of bulk mergers are pairs of first generation BH. Additionally, mergers at a migration trap grow an IMBH with typical merger mass ratios $$\tilde{q}\sim 0.1$$. Ongoing LIGO non-detections of black holes $$\gt 10^{2}\, \mathrm{M}_{\odot }$$ puts strong limits on the presence of migration traps in AGN discs (and therefore AGN disc density and structure) as well as median AGN disc lifetime. The highest merger rate occurs for this channel if AGN discs are relatively short-lived (≤1 Myr) so multiple AGN episodes can happen per Galactic nucleus in a Hubble time. 

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4. LIGO–Virgo correlations between mass ratio and effective inspiral spin: testing the active galactic nuclei channel

   https://doi.org/10.1093/mnras/stac1570  

   McKernan, B.; Ford, K. E. S.; Callister, T.; Farr, W. M.; O’Shaughnessy, R.; Smith, R.; Thrane, E.; Vajpeyi, A. (June 2022, Monthly Notices of the Royal Astronomical Society)

   ABSTRACT Observations by LIGO–Virgo of binary black hole mergers suggest a possible anticorrelation between black hole mass ratio (q = m2/m1) and the effective inspiral spin parameter χeff, the mass-weighted spin projection on to the binary orbital angular momentum. We show that such an anticorrelation can arise for binary black holes assembled in active galactic nuclei (AGNs) due to spherical and planar symmetry-breaking effects. We describe a phenomenological model in which (1) heavier black holes live in the AGN disc and tend to spin-up into alignment with the disc; (2) lighter black holes with random spin orientations live in the nuclear spheroid; (3) the AGN disc is dense enough to rapidly capture a fraction of the spheroid component, but small in radial extent to limit the number of bulk disc mergers; (4) migration within the disc is non-uniform, likely disrupted by feedback from migrators or disc turbulence; (5) dynamical encounters in the disc are common and preferentially disrupt binaries that are retrograde around their centre of mass, particularly at stalling orbits, or traps. Comparisons of predictions in (q, χeff) parameter space for the different channels may allow us to distinguish their fractional contributions to the observed merger rates. 

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5. Black hole, neutron star, and white dwarf merger rates in AGN discs

   https://doi.org/10.1093/mnras/staa2681  

   McKernan, B; Ford, K E; O’Shaughnessy, R (September 2020, Monthly Notices of the Royal Astronomical Society)

   null (Ed.)

   ABSTRACT Advanced LIGO and Advanced Virgo are detecting a large number of binary stellar origin black hole (BH) mergers. A promising channel for accelerated BH merger lies in active galactic nucleus (AGN) discs of gas around supermasssive BHs. Here, we investigate the relative number of compact object (CO) mergers in AGN disc models, including BH, neutron stars (NS), and white dwarfs, via Monte Carlo simulations. We find the number of all merger types in the bulk disc grows ∝ t1/3 which is driven by the Hill sphere of the more massive merger component. Median mass ratios of NS–BH mergers in AGN discs are $$\tilde{q}=0.07\pm 0.06(0.14\pm 0.07)$$ for mass functions (MF) M−1(− 2). If a fraction fAGN of the observed rate of BH–BH mergers (RBH–BH) come from AGN, the rate of NS–BH (NS–NS) mergers in the AGN channel is $${R}_{\mathrm{ BH}\!-\!\mathrm{ NS}} \sim f_{\mathrm{ AGN}}[10,300]\, \rm {Gpc}^{-3}\, \rm {yr}^{-1},({\mathit{ R}}_{NS\!-\!NS} \le \mathit{ f}_{AGN}400\, \rm {Gpc}^{-3}\, \rm {yr}^{-1}$$). Given the ratio of NS–NS/BH–BH LIGO search volumes, from preliminary O3 results the AGN channel is not the dominant contribution to observed NS–NS mergers. The number of lower mass gap events expected is a strong function of the nuclear MF and mass segregation efficiency. CO merger ratios derived from LIGO can restrict models of MF, mass segregation, and populations embedded in AGN discs. The expected number of electromagnetic (EM) counterparts to NS–BH mergers in AGN discs at z < 1 is $$\sim [30,900]\, {\rm {yr}}^{-1}(f_{\mathrm{ AGN}}/0.1)$$. EM searches for flaring events in large AGN surveys will complement LIGO constraints on AGN models and the embedded populations that must live in them. 

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