http://arxiv.org/abs/2102.04467
Long-term neutrino-radiation hydrodynamics simulations in full general relativity are performed for rotating massive stars that are evolved from He-stars with their initial masses of $20$ and $32M_\odot$. It is shown that if the collapsing stellar core has sufficient angular momentum, the rotationally-supported proto-neutron star (PNS) survives for seconds accompanying the formation of a massive torus of mass larger than $1\,M_\odot$. Subsequent mass accretion onto the central region produces a massive and compact central object, and eventually enhances the neutrino luminosity beyond $10^{53}$ erg/s, resulting in a very delayed neutrino-driven explosion in particular toward the polar direction. The kinetic energy of the explosion can be appreciably higher than $10^{52}$ erg for a massive progenitor star and compatible with that of energetic supernovae like broad-line type-Ic supernovae. By the subsequent accretion, the massive PNS collapses eventually into a rapidly spinning black hole, which could be a central engine for gamma-ray bursts if a massive torus surrounds it.
S. Fujibayashi, K. Takahashi, Y. Sekiguchi, et. al.
Wed, 10 Feb 21
25/64
Comments: 7 pages, 4 figures, submitted to ApJ. Comments are welcome
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