Enhanced cosmological perturbations and the merger rate of PBH binaries

Abstract

The rate of merger events observed by LIGO/Virgo can be used in order to probe the fraction f of dark mater in the form of Primordial Black Holes. Here, we consider the merger rate of PBH binaries, accounting for the effect of cosmological perturbations on their initial eccentricity e. The torque on the binaries receives significant contributions from a wide range of scales, that goes from the size of the horizon at the time when the binary forms, down to the co-moving size of the binary. In scenarios where PBH are formed from adiabatic perturbations, it is natural to expect an enhancement of the power spectrum P at small scales, where it is poorly constrained observationally. The effect can then be quite significant. For instance, a nearly flat spectrum with amplitude P 10-7 on scales smaller than 10 Mpc-1 gives a contribution j2 103 P, where j= (1-e2)1/2 is the dimensionless angular momentum parameter of the binaries. This contribution can dominate over tidal torques from neighboring PBHs for any value of f. Current constraints allow for a power spectrum as large as P 10-5 at the intermediate scales 103-105 Mpc-1, comparable to the co-moving size of the binaries at the time of formation. In particular, this can relax current bounds on the PBH abundance based on the observed LIGO/Virgo merger rate, allowing for a fraction f 10\% of dark matter in PBH of mass 30 M. We investigate the differential merger rate (m1,m2), as a function of the masses of the binary components, and the corresponding ``universality" coefficient α = -(m1+m2)2 ∂2 /∂ m1∂ m2, concluding that merger rates may provide valuable information on the spectrum of primordial cosmological perturbations at currently uncharted lengthscales.