Second-Generation Mass Peak in the Gravitational-Wave Population as a Probe of Globular Clusters

Abstract

Gravitational-wave observations have revealed an excess of binary black hole mergers with primary masses near 35\,M. We show that if this feature originates from dynamical formation in dense stellar systems, and if the pair-instability supernova truncates the first-generation black hole mass spectrum, then second-generation mergers inevitably produce a second peak near 70\,M. This structure reflects the suppression of first-generation black holes above a characteristic mass and the accumulation of merger remnants near twice that scale. Its location is robust, whereas its amplitude depends strongly on cluster initial conditions. Using a large suite of cluster population-synthesis models, we show that current gravitational-wave data already constrain the birth properties of globular clusters, irrespective of their overall contribution to the observed population. If clusters dominate mergers above the pair-instability scale, these constraints tighten further and imply a minimum first-generation merger rate of R(m1 ≤ 50\,M) ≥ 0.099\,Gpc-3\,yr-1 (99\% confidence). We further show that a drop or gap in the secondary black hole mass spectrum is not a robust signature of a cluster origin for high-mass mergers within the pair-instability mass gap. A confirmed excess near 70\,M would support a dynamical origin of the 35\,M feature and provide independent evidence for a pair-instability mass gap with a lower edge at 50M.