The fate of rotating massive stars across cosmic times
R. Hirschi, K. Goodman, G. Meynet, A. Maeder, S. Ekstr\"om, P. Eggenberger, C. Georgy, Y. Sibony, N. Yusof, S. Martinet, Vishnu Varma, K. Nomoto

TL;DR
This study uses extensive stellar models to analyze how rotation and metallicity influence the evolution, remnants, and supernova types of massive stars across cosmic history, revealing key dependencies and predictions.
Contribution
It provides a comprehensive grid of models showing the impact of rotation and metallicity on massive star fate, including remnant types and supernova predictions, across a wide parameter space.
Findings
Rotation favors black hole formation at lower masses.
Maximum black hole mass is below 50 solar masses at higher metallicities.
A pair-instability mass gap exists between 90 and 150 solar masses.
Abstract
The initial mass and metallicity of stars both have a strong impact on their fate. Stellar axial rotation also has a strong impact on the structure and evolution of massive stars. In this study, we exploit the large grid of GENEC models, covering initial masses from 9 to 500 and metallicities ranging from (nearly zero) to 0.02 (supersolar), to determine the impact of rotation on their fate across cosmic times. Using the carbon-oxygen core mass and envelope composition as indicators of their fate, we predict stellar remnants, supernova engines, and spectroscopic supernova types for both rotating and non-rotating stars. We derive rates of the different supernova and remnant types considering two initial mass functions to help solve puzzles such as the absence of observed pair-instability supernovae. We find that rotation significantly alters the remnant type and…
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