http://arxiv.org/abs/2011.05332
We study the population properties of merging binary black holes in the second LIGO–Virgo Gravitational-Wave Transient Catalog, assuming they are all forming dynamically in gravitationally bound clusters. Using a phenomenological population model, we infer the mass and spin distribution of first-generation black holes, while searching for hierarchical mergers. Considering a range of cluster masses, we see compelling evidence for hierarchical mergers for clusters with escape velocities $\gtrsim 100~\mathrm{km\,s^{-1}}$. For our highest-likelihood cluster mass, we find that at least one catalog binary contains a second-generation black hole with $>99.99\%$ probability, the hierarchical model is preferred over an alternative model with no hierarchical mergers (Bayes factor $\mathcal{B} = 25000$), GW190521 is favored to contain two second-generation black holes with odds $\mathcal{O}>700$, and GW190517, GW190519, GW190602, GW190620, and GW190706 are mixed-generation binaries with $\mathcal{O} > 10$. However, results depend strongly on the cluster escape velocity, with more modest evidence for hierarchical mergers when the escape velocity is $\lesssim 100~\mathrm{km\,s^{-1}}$. Assuming all binary black holes are formed dynamically in globular clusters with escape velocities on the order of tens of $\mathrm{km\,s^{-1}}$, GW190519 is favored to include a second-generation black hole with odds $\mathcal{O}>1$. In this case, we find that $99\%$ of black holes from the inferred total population are less than $48 M_{\odot}$, and that this constraint is robust under our choice of prior on the maximum black hole mass.
C. Kimball, C. Talbot, C. Berry, et. al.
Thu, 12 Nov 20
52/68
Comments: To be submitted; 14 pages, 12 figures, 1 appendix
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