http://arxiv.org/abs/2205.15340
Current gravitational-wave observations set the most stringent bounds on the abundance of primordial black holes (PBHs) in the solar mass range. This constraint, however, inherently relies on the merger rate predicted by PBH models. Previous analyses have focused mainly on two binary formation mechanisms: early Universe assembly out of decoupling from the Hubble expansion and dynamical capture in present-day dark matter structures. Using reaction rates of three-body processes studied in the astrophysical context, we show that, under conservative assumptions, three-body interactions in PBH halos efficiently produce binaries and significantly contribute to the overall merger rate, provided PBHs make up a sufficient fraction of the dark matter. Those binaries form at high redshift in Poisson-induced PBH small-scale structures and a fraction is predicted to coalesce and merge within the current age of the Universe, at odds with the dynamical capture scenario where they merge promptly. Our results enable LIGO/Virgo/KAGRA constraints on the PBH abundance to set stronger bounds in this interesting mass range, and have important implications for clustered PBH scenarios that might evade such constraints.
G. Franciolini, K. Kritos, E. Berti, et. al.
Wed, 1 Jun 22
32/65
Comments: 13 pages, 3 figures
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