Identifying Proca-star mergers via consistent ultralight-boson mass estimates across gravitational-wave events

Abstract

While black-hole and neutron-star mergers are the most plausible sources of current gravitational-wave observations, mergers of exotic compact objects may mimic these signals. Proca stars -- Bose-Einstein condensates of complex vector ultralight bosons -- have gained significant attention for their potential to replicate certain gravitational-wave events while yielding consistent estimates of the boson mass μB forming the stars. Using a mixture model within a Bayesian framework, we demonstrate that consistent boson-mass estimates across events can be exploited to obtain conclusive evidence for the existence of a number n of Proca-star families characterized by respective boson masses μBi, even if no individual event can be conclusively identified as such. Our method provides posterior distributions for n and μBi. Applying this framework to the high-mass events GW190521, GW190426\190642 and GW200220\061928, we obtain a Bayes Factor Bn=0n=1=2 against the Proca-star hypothesis, primarily rooted in the limitation of current Proca-star merger signal models to intrinsically weak head-on cases. We show that conclusive evidence Bn=1n=0 ≥ 5 could be achieved after 5 to 9 observations of similar event sets, at the 90\% credible level. Our framework provides a new way to detect exotic compact objects, somewhat using gravitational-wave detectors as particle detectors.