Neutrino-Cooled Accretion Disks around Spinning Black Hole
Abstract
We calculate the structure of accretion disks around Kerr black holes for accretion rates 0.001 - 10 Msun/s. Such disks are plausible candidates for the central engine of gamma-ray bursts. Our disk model is fully relativistic and treats accurately microphysics of the accreting matter: neutrino emissivity, opacity, electron degeneracy, and nuclear composition. The neutrino-cooled disk forms above a critical accretion rate that depends on the black hole spin. The disk has the ``ignition'' radius rign where neutrino flux rises dramatically, cooling becomes efficient, and the proton-to-nucleon ratio Ye drops. Other characteristic radii are ralpha where most of alpha-particles are disintegrated, rnu where the disk becomes neutrino-opaque, and rtrap where neutrinos get trapped and advected into the black hole. We find ralpha, rign, rnu, rtrap and show their dependence on the accretion rate. We discuss the qualitative picture of accretion and present sample numerical models of the disk structure. All neutrino-cooled disks regulate themselves to a characteristic state such that: (1) electrons are mildly degenerate, (2) Ye ~ 0.1, and (3) neutrons dominate the pressure in the disk.
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