Some results on the evolution of primordial black holes

Horvath, J. E.; Custódio, P. S.

doi:10.1590/s0103-97332005000700053

Cited by 5 publications

(3 citation statements)

References 8 publications

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“…Some authors show that the calculated accretion rates for simplified models are sufficiently high to transform a PBH to solar mass black holes (Sivaram 2001). As cited above, others make claims that when more complicated accretion models are considered, the mass accretion rates for both stationary and moving PBHs are insufficient to appreciably modify the mass of the PBH except in very high Lorentz factor models (Custodio and Horvath 2002;Horvath and Custodio 2005). We show, using our own simplified model, that the accretion rates of moving PBH is insufficient for the PBH to reach solar masses, in agreement with the conclusions of Custodio and Horvath (2002).…”

Section: Introductionsupporting

confidence: 87%

“…By comparing our accretion rates to that of the results in Horvath and Custodio (2005), we also find that our models of traveling black holes do not substantially increase their mass accretion rate. This leads us to agree with the conclusions of Custodio and Horvath (2002) and Horvath and Custodio (2005), that a primordial black hole must sustain a very large boost to begin to accrete sufficient amounts of matter to completely avoid Hawking radiation. When comparing fluid models for Γ = 1.1, 5/4, 4/3, and 3/2 in figures B1, 7, B3, and B2, we find that the stiffer the fluid Γ → 2, the faster the accretion rate.…”

Section: Discussionsupporting

confidence: 54%

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Ultrarelativistic Bondi–Hoyle accretion – I. Axisymmetry

Penner¹

2012

Monthly Notices of the Royal Astronomical Society

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An ultrarelativistic relativistic study of axisymmetric Bondi-Hoyle accretion onto a moving Kerr black hole is presented. The equations of general relativistic hydrodynamics are solved using high resolution shock capturing methods. In this treatment we consider the ultrarelativistic limit wherein one may neglect the baryon rest mass density. This approximation is valid in the regime where the internal energy of the system dominates over the rest mass energy contribution from the baryons. The parameters of interest in this study are the adiabatic constant Γ, and the asymptotic speed of the fluid, v ∞ . We perform our simulations in three different regimes, subsonic, marginally supersonic, and supersonic, but the primary focus of this study is the parameter regime in which the flow is supersonic, that is when v ∞ c ∞ s . As expected from previous studies the supersonic regimes reveal interesting dynamics, but even more interesting is the presence of a bow shock in marginally supersonic systems. A range of parameter values were investigated to attempt to capture possible deviations from steady state solutions, none were found. To show the steady state behaviour of each of the flows studied we calculate the energy accretion rates on the Schwarzschild radius. Additionally, we also find that the accretion flows are dependent on the location of the computational boundary, that if the computational boundary is located too close to the black hole the calculated flow profiles are marred with numerical artifacts. This is a problem not found in previous relativistic models for ultrarelativistic hydrodynamic systems.

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Section: Introductionsupporting

confidence: 87%

Section: Discussionsupporting

confidence: 54%

Ultrarelativistic Bondi–Hoyle accretion – I. Axisymmetry

Penner¹

2012

Monthly Notices of the Royal Astronomical Society

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“…In the non-commutative case discussed here, however, the maximum temperature occurs way before Planck temperature, and so the speed is negligible for most part of the evolution before M m is reached. Now, according to [54] and [64], if the Hawking temperature of a black hole reaches T ≈ 2.7 K at the current epoch, it will attain thermal equilibrium with the cosmic microwave background (CMB) photons and thus stop evaporating. While this may be true for larger black holes, it is not what happens in our case when the black holes are microscopic.…”

Section: Jcap07(2021)041mentioning

confidence: 99%

Feasibility of primordial black hole Remnants as dark matter in view of Hawking radiation recoil

Gennaro¹,

Ong²

2021

J. Cosmol. Astropart. Phys.

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It has recently been suggested that black hole remnants of primordial origin are not a viable dark matter candidate since they would have far too large a velocity due to the recoil of Hawking radiation. We re-examined this interesting claim in more details and found that it does not rule out such a possibility. On the contrary, for models based on non-commutativity of spacetime near the Planck scale, essentially the same argument can be used to estimate the scale at which the non-commutativity effect becomes important. If dark matter “particles” are non-commutative black holes that have passed the maximum temperature, this implies that the non-commutative scale is about 100 times the Planck length. The same analysis applies to other black hole remnants whose temperature reaches a maximum before cooling off, for example, black holes in asymptotically safe gravity.

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Mass Evolution of Schwarzschild Black Holes

Santi

Santarelli

2019

Braz J Phys

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Some results on the evolution of primordial black holes

Cited by 5 publications

References 8 publications

Ultrarelativistic Bondi–Hoyle accretion – I. Axisymmetry

Ultrarelativistic Bondi–Hoyle accretion – I. Axisymmetry

Feasibility of primordial black hole Remnants as dark matter in view of Hawking radiation recoil

Mass Evolution of Schwarzschild Black Holes

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