Masaru Shibata, Yuichiro Sekiguchi
A radiation-magnetohydrodynamic simulation for the black hole-torus system is performed in the framework of full general relativity for the first time. A truncated moment formalism is employed for a general relativistic neutrino radiation transport. Several systems in which the black hole mass is $M_{\rm BH}=3$ or $6M_{\odot}$, the black hole spin is zero, and the torus mass is $\approx 0.14$--$0.38M_{\odot}$ are evolved as models of the remnant formed after the merger of binary neutron stars or black hole-neutron star binaries. The equation of state and microphysics for the high-density and high-temperature matter are phenomenologically taken into account in a semi-quantitative manner. It is found that the temperature in the inner region of the torus reaches $\agt 10$ MeV which enhances a high luminosity of neutrinos $\sim 10^{51}$ ergs/s for $M_{\rm BH}=6M_{\odot}$ and $\sim 10^{52}$ ergs/s for $M_{\rm BH}=3M_{\odot}$. It is shown that neutrinos are likely to be emitted primarily toward the outward direction in the vicinity of the rotational axis and their energy density may be high enough to launch a low-energy short gamma-ray burst via the neutrino-antineutrino pair-annihilation process with the total energy deposition $\sim 10^{47}$--$10^{49}$ ergs. It is also shown in our model that for $M_{\rm BH}=3M_{\odot}$, the neutrino luminosity is larger than the electromagnetic luminosity while for $M_{\rm BH}=6M_{\odot}$, the neutrino luminosity is comparable to or slightly smaller than the electromagnetic luminosity.
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http://arxiv.org/abs/1206.5911
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