Growth of Metal-Enriched Supermassive Stars by Accretion and Collisions
Abstract
Supermassive stars (SMSs) are candidate progenitors of massive black hole seeds and may contribute to anomalous abundance patterns in high-redshift galaxies and globular clusters. Recent radiation-hydrodynamic simulations indicate that SMSs can form at finite metallicity, not only in metal-free direct-collapse conditions. We model SMS growth with GENEC over Z/Z=10-5-10-2 using simulation-motivated accretion histories. The final masses reach 7.2×104\,M at 10-5\,Z and 2.3×103\,M at 10-2\,Z. Models are evolved through the pre-main sequence and core H-burning phases, terminating at the onset of general-relativistic instability for Z10-4\,Z or at core He exhaustion for Z10-3\,Z. The dominant mass growth channel transitions from collision-driven to accretion-driven between Z=10-4 and 10-3. With stellar lifetimes remaining nearly constant at 1.8-2.0 Myr, collisions do not significantly rejuvenate the star, implying that collision driven runaway collapse cannot proceed in isolation and must be supplemented, and likely dominated by gas accretion. We further compute the critical inflow rate required to keep the stellar envelope inflated, M crit, which decreases with increasing Z and decreasing central mass fraction of hydrogen (X c). The critical rate falls below 10-5\,M\, yr-1 at X c=0.60 for 10-2Z. This indicates that SMSs with 0.01~Z are cool supergiants during most of their lifetimes, where UV photon emissivity and radiative feedback is strongly suppressed. Overall, SMS evolution remains viable up to Z0.01\,Z, supporting SMS formation in proto-globular clusters and other metal-enriched dense environments.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.