Supermassive Black Hole Assembly from Heavy Seeds with Dynamical Friction in the BRAHMA Simulations: Implications for JWST, LISA, and the Local Universe

Abstract

The JWST discoveries of supermassive black holes (BHs) at z 5 may provide key insights into their seeding origins. Using new [18-72~ Mpc]3 BRAHMA cosmological simulations, we investigate how variations in heavy-seed prescriptions, coupled with a subgrid dynamical friction model, shape BH populations at z 5 and z 0. We consider two "lenient'' seed models, in which all halos containing sufficient dense & metal-poor gas form 104 and 105~M seeds, and a "strict'' seed model, in which 105 M seeds form only under additional constraints motivated by direct collapse black hole formation. By z 5, all models produce M*-M BH relations broadly consistent with the observed local Universe for M*109~M galaxies, but only the lenient scenarios generate systems near the upper envelope of the observed local scatter. In galaxies hosting M BH 108-109~M BHs, lenient production of 105~M seeds also produces multiple overmassive systems with M BH/M* 0.01. Although their growth is dominated by seeding and mergers, these systems reach luminosities of 1043-1045erg s-1, comparable to those inferred for JWST-detected BHs. As a key observational signature, the lenient seed models yield merger rates of 100yr-1 and near-unity local BH occupation fractions even in galaxies with M* 107~M. In contrast, the strict seed model produces merger rates of only 1yr-1 and local occupation fractions of 10\% for galaxies with M* 108~M. Future gravitational-wave event rates and measurements of local BH occupation fractions will therefore provide strong constraints on the dominant pathways responsible for high-redshift BH assembly.