Hot, Dense Matter Accretion onto a Black Hole

Abstract

The accretion of hot, dense matter which consists of heavy nuclei, free nucleons, degenerated electrons, photons and neutrinos is studied. The composition of free nucleons and their chemical potentials are provided through the equation of state for hot, dense matter proposed by Lattimer and Swesty(1991). When the mass of a central black hole and the accretion rate are selected as MBH ≈ 3 M and M ≈ 0.1 M-1, which provide the typical luminosity of gamma ray bursts(GRBs), the fraction of free protons in the accreting matter becomes very small, Yp ≈ 10-4, while that of free neutrons is closer to unity, Yn ≈ 0.7. Then the antielectron neutrinos νe can freely escape through the disk but the electron neutrinos νe are almost absorbed in the disk. Thus the frequent collisions of νe with νe over the disk couldn't be occurred. The accretion disk is cooled mainly by νe, which suppresses the increase of temperature and increases the density in the accreting matter such as T ≈ 3× 1010K and ρ≈ 3× 1013g/cm3 at the inner side of the disk. The scattering optical depths of νe and νe then reach to be very large, τs(νe) ≈ τs(νe) ≈ 102. Thus the accretion disk could be thermally unstable within the duration of diffusion time of neutrinos, tdiff ≈ 10(ms).

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