Repopulating the pair-instability mass gap without sustained growth to massive IMBHs: the case of 47\,Tuc

Abstract

We model the formation and retention of the most massive black hole (BH) in 47~Tuc using the semi-analytical code cBHBd, coupling cluster evolution with binary BH dynamics and computing merger-remnant masses, spins, and gravitational-wave recoil kicks via numerical-relativity surrogate prescriptions. We evolve 80\,000 cluster realisations spanning initial masses, densities, IMFs, and metallicities, in both a baseline scenario (m max = 130\,M) and an extended-IMF scenario with \,50-110 primordial BH seeds above the pair-instability gap (M BH 130-700\,M). Selecting models reproducing 47~Tuc's present-day mass and half-mass radius, we find hierarchical mergers alone yield a most massive retained BH of M BH 45-70\,M with spin BH 0.65, limited to \,1-3 mergers, as second-generation remnants acquire spin 0.7 that amplifies recoil kicks in subsequent generations. When primordial seeds are included, the retained-mass distribution becomes bimodal -- in \,90\% of realisations all seeds are ejected, but in \,10\% a massive seed (M BH 450\,M) survives -- while the joint mass-spin distribution is trimodal; seeds surviving via stellar-mass BH mergers retain low spin ( 0.3), whereas seed-seed mergers produce high-mass, high-spin remnants ( 0.65-0.7), yielding 90th-percentile retained masses of \,500-1100\,M. Both scenarios are consistent with the 3σ dynamical upper limit of 578\,M. Our results favour a dark-remnant subsystem over a single massive IMBH and provide a spin-mass diagnostic testable with LIGO-Virgo-KAGRA, the Einstein Telescope, Cosmic Explorer, and LISA.