The effects of rotation, metallicity and magnetic field on the islands of failed supernovae

TL;DR

This study explores how rotation, metallicity, and magnetic fields influence the explodability of massive stars, revealing complex effects on failed supernovae and gamma-ray burst formation, with implications for black hole origins.

Contribution

It provides detailed stellar evolution simulations considering rotation, metallicity, and magnetic fields, clarifying their roles in failed supernovae and gamma-ray burst production.

Findings

Rapid rotation lowers the ZAMS mass threshold for carbon ignition.

High metallicity inhibits rotational mixing and gamma-ray burst formation.

Magnetic fields can increase pre-collapse mass and favor failed supernovae.

Abstract

Failed supernovae (FSN) are a possible channel for the formation of heavy stellar-mass black holes ($M_{ BH}>\sim 30$ M$_\odot$). However, the effects of metallicity, rotation and magnetic field on the islands of explodabilty of massive stars are not clear. Here, we simulate the stellar structure and evolution in the mass range between 6 and 55 $M_{\odot}$ with different initial rotational velocities, metallicities, and magnetic fields from zero-age main sequence (ZAMS) to pre-collapse. We find that the rapid rotating stars can remain lower $\rm ^{12}C$ mass fraction at the time of C ignition, which allows the transition, from convective carbon burning to radiative burning, to occur at lower $M_{\rm ZAMS}$ than those from stars without rotation. However, the rapid rotation is unfavorable for FSN occurring but is conducive to long gamma-ray bursts (lGRBs) because it results in the specific angular momentum in the CO core is greater than the last stable orbit at core collapse. The increasing metallicity does not affect FSN islands, but high metallicity inhibits rotational mixing and is unfavorable for producing lGRBs. A magnetic field can constrain the mass-loss rate even for rapid rotating stars, resulting in higher mass at pre-collapse. The magnetic braking triggered by the magnetic field can reduce the rotation velocity for high-metallicity models, which decreases the specific angular momentum in the CO core and is favorable for FSN occurring. We suggest that the heavy-mass black holes detected by LIGO may originate from rapidly rotating massive stars with strong magnetic fields, rather than those with very low metallicity.