Astronomy and Astrophysics – Astrophysics
Scientific paper
2005-04-26
Phys.Rev. D71 (2004) 084013
Astronomy and Astrophysics
Astrophysics
Scientific paper
10.1103/PhysRevD.71.084013
We perform axisymmetric simulations for gravitational collapse of a massive iron core to a black hole in full general relativity. The iron cores are modeled by $\Gamma = 4/3$ equilibrium polytrope for simplicity and a parametric equation of state is adopted during the collapse. Performing simulations for a wide variety of initial conditions changing the mass, the angular momentum, the rotational velocity profile of the core, and the parameters of the equations of state (which are chosen so that the maximum mass of the cold spherical polytrope is $\approx 1.6M_{\odot}$), a criterion for the prompt black hole formation is clarified in terms of them. It is found that (i) with the increase of the thermal energy generated by shocks, the threshold mass for the prompt black hole formation is increased by 20--40%, (ii) the rotational centrifugal force increases the threshold mass by $\alt 25%$, (iii) with the increase of the degree of differential rotation, the threshold mass is also increased, and (iv) the amplification factors shown in the results (i)--(iii) depend sensitively on the equation of state. We also find that the collapse dynamics and the structure of the shock formed at the bounce depend strongly on the stiffness of the adopted equation of state. In particular, as a new feature, a strong bipolar explosion is observed for the collapse of rapidly rotating iron cores with an equation of state which is stiff in subnuclear density and soft in supranuclear density. Gravitational waves are computed in terms of a quadrupole formula. It is also found that the waveform depends sensitively on the equations of state.
Sekiguchi Yu-ichirou
Shibata Masaru
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