SEEDZ: Rapid Galaxy Assembly as a Pathway to Supermassive Stars, Dense Stellar Environments and Massive Black Hole Seeds

Abstract

We investigate the assembly history of early galaxies in the SEEDZ hydrodynamic simulations, to investigate the high inflow rates believed to be required for the formation of supermassive stars (SMSs), dense stellar clusters and subsequently heavy seed black holes. Using a heavy seed formation criteria of >1 M yr-1 flowing into 10 pc regions, we find that heavy seeds form in halos that grow rapidly compared to those halos that never meet the criteria. Halos with growth rates of 1 M yr-1 at their virial radius (scales of a few hundred pc) are able to sustain a flow rate of 0.1 M yr-1 into the inner 1 pc of the halo, maintaining higher density environments within the central 10 - 100~pc. These halos continue to grow rapidly after their initial collapse, typically forming heavy seeds 100 Myr after forming their first stars and stellar mass black holes. By z=10, most heavy seeds form in regions of near-solar metallicity, although a minority of heavy seeds do continue to form in low metallicity (10-2 Z) regions. Under the assumption that a SMS forms as the progenitor to a heavy seed if it forms in a region of low (10-2 Z) metallicity, and can sustain high accretion rates above 0.02 M yr-1 throughout the SMS lifetime of 2 Myr, we find a number density of SMSs of 0.1 cMpc-3, meaning that only a fraction of 10-4 of these SMSs would need to be visible to JWST to account for the observed population of Little Red Dot galaxies.