GW231123: Likely a product of successive mergers from $\sim 10 $ stellar-mass black holes

TL;DR

This paper analyzes the massive binary black hole merger GW231123, proposing it originated from successive hierarchical mergers of multiple stellar-mass black holes, challenging traditional stellar evolution models.

Contribution

It provides evidence that GW231123 is a multi-generation merger remnant, supporting the idea that repeated mergers can produce more massive black holes.

Findings

GW231123 is a high-spin, multi-generation merger remnant.

Both components likely originated from successive mergers of ~6 and ~4 first-generation BHs.

Repeated mergers can produce intermediate-mass black holes.

Abstract

GW231123 is an exceptionally massive binary black hole (BBH) merger with unusually high component spins. Such extreme properties challenge conventional stellar evolution models predicting a black hole mass gap due to pair-instability supernovae. We test possible formation scenarios for GW231123 using population-informed priors on BH spin distributions, in light of population properties built on the previous (GWTC-3) data. Our analysis shows that GW231123 belongs to the high-spin subpopulation that is naturally interpreted as hierarchical BBH mergers. By comparing the spin magnitudes and component masses of GW231123 to those of the remnants of previous mergers, we show that both components of GW231123 are multi-generation ($>$2G) merger remnants, and plausibly originated from the successive mergers of $\sim 6$ and $\sim 4$ first-generation BHs, respectively. This suggests that repeated mergers can be frequent and even more massive intermediate-mass black holes may be produced. Thus mechanisms that can efficiently harden the BBHs' orbits are required, e.g., gas dynamical friction in the disks of active galactic nuclei.