Rotating Supermassive Pop III Stars On The Main Sequence

TL;DR

This study models the evolution of rotating Population III supermassive stars, revealing how rotation influences their structure, chemical yields, and the properties of resulting black holes, with implications for early universe observations.

Contribution

First comprehensive models of rotating Pop III supermassive stars including rotation effects, showing impacts on stellar evolution, chemical mixing, and black hole spin characteristics.

Findings

Rotation enlarges convective cores and extends stellar lifetimes.

Core rotation remains slow, leading to low black hole spin parameters.

Rotation affects chemical yields and mass-loss rates in SMSs.

Abstract

The detection of billion-solar-mass supermassive black holes (SMBHs) within the first billion years of cosmic history challenges conventional theories of black hole formation and growth. Simultaneously, recent JWST observations revealing exceptionally high nitrogen-to-oxygen abundance ratios in galaxies at high redshifts raise critical questions about rapid chemical enrichment mechanisms operating in the early universe. Supermassive stars (SMSs) with masses of 1000 to 10000 M$_{\odot}$ are promising candidates to explain these phenomena, but existing models have so far neglected the pivotal role of stellar rotation. Here, we present the first comprehensive evolutionary models of rotating Pop III SMSs computed using the GENEC stellar evolution code, including detailed treatments of rotation-induced chemical mixing, angular momentum transport, and mass loss driven by the $\Omega\Gamma$ limit. We demonstrate that rotation significantly enlarges the convective core and extends stellar lifetimes by up to 20%, with moderate enhancement of mass-loss rates as stars approach critical rotation thresholds. Our results further indicate that the cores of SMSs rotate relatively slowly (below $\sim 200$ km s$^{-1}$), resulting in dimensionless spin parameters $a* < 0.1$ for intermediate-mass black hole (IMBH) remnants that are notably lower than theoretical maximum spins. These findings highlight rotation as a key factor in determining the structural evolution, chemical yields, and black hole spin properties of SMSs, providing critical insights to interpret observational signatures from the high-redshift universe.