The cosmic merger rate density of compact objects: impact of star formation, metallicity, initial mass function and binary evolution

Filippo Santoliquido, Michela Mapelli, Nicola Giacobbo, Yann Bouffanais, M. Celeste Artale

Published 2020-09-08Version 1

We evaluate the redshift distribution of binary black hole (BBH), black hole - neutron star binary (BHNS) and binary neutron star (BNS) mergers, exploring the main sources of uncertainty: star formation rate (SFR) density, metallicity evolution, common envelope, mass transfer via Roche lobe overflow, natal kicks, core-collapse supernova model and initial mass function. Among binary evolution processes, uncertainties on common envelope ejection have a major impact: the local merger rate density of BNSs varies from $\sim{}10^3$ to $\sim{}20$ Gpc$^{-3}$ yr$^{-1}$ if we change the common envelope efficiency parameter from $\alpha_{\rm CE}=7$ to 0.5, while the local merger rates of BBHs and BHNSs vary by a factor of $\sim{}2-3$. The BBH merger rate changes by one order of magnitude, when $1 \sigma$ uncertainties on metallicity evolution are taken into account. In contrast, the BNS merger rate is almost insensitive to metallicity. Hence, BNSs are the ideal test bed to put constraints on uncertain binary evolution processes, such as common envelope and natal kicks. Our BNS models match the cosmic merger rate inferred from LIGO - Virgo data only for large values of $\alpha_{\rm CE}$ ($\ge{}3$) and only if the magnitude of natal kicks scales with the mass of the ejecta.