The gravitational wave event GW231123, with component black hole masses lying within or above the pair-instability mass gap, poses a significant challenge to current stellar evolution models. In this work, we describe how we investigated its origin by coupling the galaxy formation model with the cluster population synthesis code and using two distinct binary population synthesis codes, and. This framework allowed us, for the first time, to reconstruct the life cycle of GW231123-like candidates within the same cosmological simulation, enabling a self-consistent comparison between different formation channels. Although both population synthesis codes can in principle produce black holes compatible with GW231123, we find that isolated binary evolution fails to reproduce the inferred merger redshift. In, massive black hole binaries form with semi-major axes >10³, ̊m R_⊙, preventing coalescences within a Hubble time. In GAMESH RAPSTER SEVN BSEEMP SEVN BSEEMP, candidates arise only at extremely low metallicities (̊m Z ≈ 10^ -10), which contribute negligibly to the star formation rate density in our overdense simulated volume. Our results therefore strongly support a dynamical hierarchical origin. The observed black hole masses are naturally reproduced through successive mergers in dense globular clusters. The high dimensionless spins reported by the LIGO-Virgo-KAGRA Collaboration are consistent with this hierarchical population. We found a local merger rate density of 0. 78, ̊m Gpc^ -3, yr^ -1, with a peak at = 4-6, tracing the maximum formation rate of globular clusters in metal-poor environments (̊m Z z Overall, GW231123 may represent a benchmark event for a robust population of hierarchical black holes formed in the early Universe.
Angeloni et al. (Mon,) studied this question.