Gravitational Collapse of Rotating Supermassive Stars including Nuclear Burning Effects

Abstract

Supermassive stars (SMSs) of mass 105 M are candidates for seeds of supermassive black holes found in the center of many massive galaxies. We simulate the gravitational collapse of a rigidly rotating SMS core including nuclear burning effects in axisymmetric numerical-relativity simulation. We find that for realistic initial conditions, the nuclear burning does not play an important role. After the collapse, a torus surrounding a rotating black hole is formed and a fraction of the torus material is ejected. We quantitatively study the relation between the properties of these objects and rotation. We find that if a SMS core is sufficiently rapidly rotating, the torus and outflow mass have approximately 6\% and 1\% of the initial mass, respectively. The typical average velocity and the total kinetic energy of the outflow are 0.2~c and 1054-56 erg where c is the speed of light. Finally, we briefly discuss the possibility for observing the torus and outflow.