Litcius/Paper detail

The collapse and three-dimensional explosion of three-dimensional massive-star supernova progenitor models

David Vartanyan, Matthew S. B. Coleman, Adam Burrows

2021Monthly Notices of the Royal Astronomical Society68 citationsDOIOpen Access PDF

Abstract

ABSTRACT The explosion outcome and diagnostics of core-collapse supernovae depend sensitively on the nature of the stellar progenitor, but most studies to date have focused exclusively on one-dimensional, spherically symmetric massive star progenitors. We present some of the first core-collapse supernovae simulations of three-dimensional massive star supernovae progenitors, a 12.5- and a 15-M⊙ model, evolved in three dimensions from collapse to bounce through explosion with the radiation-hydrodynamic code fornax. We compare the results using those starting from three-dimensional progenitors to three-dimensional simulations of spherically symmetric, one-dimensional progenitors of the same mass. We find that the models evolved in three dimensions during the final stages of massive star evolution are more prone to explosion. The turbulence arising in these multidimensional initial models serves as seed turbulence that promotes shock revival. Detection of gravitational waves and neutrinos signals could reveal signatures of pre-bounce turbulence.

Topics & Concepts

PhysicsSupernovaAstrophysicsStellar evolutionType II supernovaGravitational collapseStar (game theory)StarsGravitational waveAstronomyTurbulenceShock waveNeutrinoMechanicsNuclear physicsGamma-ray bursts and supernovaeStellar, planetary, and galactic studiesPulsars and Gravitational Waves Research