Formation of supermassive stars in the first stellar clusters: Dependence on the gas temperature

TL;DR

This study investigates how gas temperature influences the formation of supermassive stars in early stellar clusters, revealing that lower temperatures and higher instability favor the creation of more massive black hole seeds.

Contribution

It introduces multiphysics simulations exploring the impact of gas temperature and gravitational instability on supermassive star formation in primordial clusters.

Findings

Central objects of ~10^4 solar masses can form via accretion and collisions.

Higher instability leads to more efficient mass accumulation (~0.95).

Warmer temperatures favor quasi-disk formation and collision-driven mass growth.

Abstract

The origin of supermassive black holes is an open question that has been explored considering gas- and collision-based formation channels to explain the high number of quasars observed in the early Universe. According to numerical simulations, supermassive stars can be formed in atomic cooling halos when protostars reach accretion rates greater than $\sim 10^{-2}~\mathrm{M_{\odot}~yr^{-1}}$ and fragmentation is inhibited on parsec scales. It remains uncertain, however, whether fragmentation on smaller scales leads to the formation of a star cluster instead of a supermassive star in the presence of possible cooling mechanisms. We explored the formation of a central massive object through collisions and the accretion of Population III stars in a primordial gas cloud in a gravitationally unstable system by varying the gas temperature and the degree of gravitational instability. We performed multiphysics simulations in the AMUSE framework with a hydrodynamical gas treatment through Smoothed-particle hydrodynamics and $N$-body dynamics for the protostars represented through sink particles. Our results show that central massive objects with masses $\sim 10^4~\mathrm{M_{\odot}}$ can be formed by accretion and collisions at different temperatures and that the most massive object can reach efficiencies of $\sim 0.61$ for atomic cooling conditions and $\sim 0.95$ for more unstable conditions. We observe a quasi-disk formation for warmer temperatures and a higher contribution through collisions to the mass of a central massive object. Our results show that the embedded cluster is in a supercompetitive accretion regime in which it obtains mass by accretion that is regulated by self-gravity. Our results suggest that in more unstable conditions with lower gas temperatures, a more massive supermassive black hole seed can form.