Magnetorotational Collapse of Supermassive Stars: Black Hole Formation, Gravitational Waves and Jets

Abstract

We perform MHD simulations in full GR of uniformly rotating stars that are marginally unstable to collapse. Our simulations model the direct collapse of supermassive stars (SMSs) to seed black holes (BHs) that can grow to become the supermassive BHs at the centers of quasars and AGNs. They also crudely model the collapse of massive Pop III stars to BHs, which could power a fraction of distant, long gamma-ray bursts (GRBs). The initial stellar models we adopt are = 4/3 polytropes seeded with a dynamically unimportant dipole magnetic field (B field). We treat initial B-field configurations either confined to the stellar interior or extending out from the interior into the stellar exterior. The BH formed following collapse has mass MBH 0.9M (where M is the mass of the initial star) and spin aBH/MBH 0.7. A massive, hot, magnetized torus surrounds the remnant BH. At t 400-550M≈ 2000-2700(M/106M)s following the gravitational wave (GW) peak amplitude, an incipient jet is launched. The disk lifetime is t 105(M/106M)s, and the jet luminosity is LEM 1051-52 ergs/s. If 1-10\% of this power is converted into gamma rays, SWIFT and FERMI could potentially detect these events out to large redshifts z 20. Thus, SMSs could be sources of ultra-long GRBs and massive Pop III stars could be the progenitors that power a fraction of the long GRBs observed at redshift z 5-8. GWs are copiously emitted during the collapse, and peak at 15(106 M/M) mHz ( 0.15(104 M/M) Hz), i.e., in the LISA (DECIGO/BBO) band; optimally oriented SMSs could be detectable by LISA (DECIGO/BBO) at z 3 (z 11). Hence 104 M SMSs collapsing at z 10 are promising multimessenger sources of coincident gravitational and electromagnetic waves.