Observing cosmological binary mergers with next generation neutrino and gravitational wave detectors

Abstract

We discuss the potential of detecting thermal neutrinos from matter-rich binary mergers, via a decades-long multi-messenger campaign involving a Mt-scale water Cherenkov neutrino detector and one or more next generation gravitational wave detectors, capable of observing mergers up to redshift z 2. The search of neutrinos in time-coincidence with gravitational wave detections will allow to identify single neutrinos from individual mergers above the background, and to study their distributions in energy, redshift and type (double neutron-star or neutron-star-black hole merger) of the candidate sources. We find that, for merger rates consistent with current LIGO-Virgo constraints, and for a 100~ Mt· yr exposure, between O(10-1) and O(10) neutrino events are expected. For extreme cases of mergers with more than 1052 ergs emitted in e, the number of events can be as large as 100, with sensitivity to mergers up to redshift z 0.5 or so. Such scenarios can already be tested with a 10~ Mt· yr exposure, resulting in constraints on the post-merger evolution of the systems being considered.