Simulations of Ellipsoidal Primordial Black Hole Formation
Abstract
We perform 3+1 relativistic numerical simulations to study primordial black hole (PBH) formation from the collapse of adiabatic super-horizon non-spherical perturbations generated from curvature fluctuations obeying random Gaussian statistics with a monochromatic power spectrum. The matter field is assumed to be a perfect fluid of an equation of state w:=P/= const. with P and being the pressure and the energy density, respectively. The initial spatial profile of the curvature perturbation is modeled with the amplitude μ and non-spherical parameters e (ellipticity) and p (prolateness) according to peak theory. We focus on the dynamics and the threshold for PBH formation in terms of the non-spherical parameters e and p. We find that the critical values (ec, pc) with a fixed value of μ closely follow a superellipse curve. With p=0, for the range of amplitudes considered, we find that the critical ellipticity for non-spherical collapse follows a decaying power law as a function of (μ-μ c,sp) with μ c,sp being the threshold for the spherical case. Our results also indicate that, for both cases of w = 1/3 and w = 1/10, small deviations from sphericity can avoid collapsing to a black hole when the amplitude is near its critical threshold. Finally we discuss the significance of the ellipticity on the rate of the PBH production.
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