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The Stellar Black Hole ()

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*Journal of High Energy Physics, Gravitation and Cosmology*,

**4**, 651-654. doi: 10.4236/jhepgc.2018.44037.

1. Introduction

In the following model, a neutron star forms the core of a stellar black hole. The collapse of a massive star creates the neutron star. Electron-positron pairs, which are produced during the collapse, cannot escape the intense gravitational field of the neutron star. They settle into a degenerate quantum state surrounding the core.

The Fermi energy for a completely degenerate $\left(T=0\right)$ gas of N/2 electrons is given by [1] [2]

${\u03f5}_{F}={\left(\frac{3{\text{\pi}}^{2}}{2}\right)}^{2/3}\frac{{\hslash}^{2}}{2m}{n}^{2/3}$ (1)

where n is the total number density of leptons. If the gas is non-relativistic, the Fermi level must be less than 0.5 MeV. Formula (1) then limits the number density to about $3\times {10}^{30}\text{\hspace{0.17em}}{\text{cm}}^{-3}$ , with the corresponding mass density $\rho =nm=3\times {10}^{3}\text{\hspace{0.17em}}\text{g}\cdot {\text{cm}}^{-3}$ . Therefore, the density of the lepton gas will be much less than that of the core $\left({\rho}_{c}=5\times {10}^{14}\text{g}\cdot {\text{cm}}^{-3}\right)$ . Clearly, the gas envelope will have little direct impact on the core.

2. The Black Hole Model

Under the assumption of spherical symmetry, the gravitational field equation and the equation of hydrostatic equilibrium are given by

$\frac{1}{{r}^{2}}\frac{\text{d}}{\text{d}r}\left({r}^{2}\frac{\text{d}\psi}{\text{d}r}\right)=4\text{\pi}G\rho $ (2)

and

$\frac{\text{d}P}{\text{d}r}=-\rho \frac{\text{d}\psi}{\text{d}r}$ (3)

If the lepton gas is assumed to be incompressible, then the density is constant, and Equation (2) gives

$\frac{\text{d}\psi}{\text{d}r}=\frac{4\text{\pi}G}{3}\rho r+\frac{K}{{r}^{2}}$ (4)

At the surface of the neutron star, $\text{d}\psi /\text{d}r=G{M}_{c}/{R}_{c}^{2}$ , where ${M}_{c}$ and ${R}_{c}$ are the mass and radius of the core. Substitute this into (4) to find

$K=G{M}_{c}\left(1-\frac{\rho}{{\rho}_{c}}\right)$ (5)

Since $\rho \ll {\rho}_{c}$ , the constant of integration $K=G{M}_{c}$ . Equations (3) and (4) then combine to give

$P=\frac{G{M}_{c}}{{R}_{c}}\rho \left(\frac{{R}_{c}}{r}-\frac{\rho}{2{\rho}_{c}}\frac{{r}^{2}}{{R}_{c}^{2}}\right)+{P}^{\prime}$ (6)

At the outer surface of the gas, $r=R$ and $P=0$ , so that the integration constant is

${P}^{\prime}=-\frac{G{M}_{c}}{{R}_{c}}\rho \left(\frac{{R}_{c}}{R}-\frac{\rho}{2{\rho}_{c}}\frac{{R}^{2}}{{R}_{c}^{2}}\right)$ (7)

This yields the pressure formula for the gas

$P=\frac{G{M}_{c}}{{R}_{c}}\rho \left\{{R}_{c}\left(\frac{1}{r}-\frac{1}{R}\right)+\frac{\rho}{2{\rho}_{c}}\frac{1}{{R}_{c}^{2}}\left({R}^{2}-{r}^{2}\right)\right\}\text{\hspace{0.17em}}\text{\hspace{0.17em}}\left({R}_{c}<r<R\right)$ (8)

The maximum pressure occurs at the surface of the core ( $r={R}_{c}$ )

${P}_{\mathrm{max}}=\frac{G{M}_{c}}{{R}_{c}}\rho \left\{\left(1-\frac{{R}_{c}}{R}\right)+\frac{\rho}{2{\rho}_{c}}\left(\frac{{R}^{2}}{{R}_{c}^{2}}-1\right)\right\}$ (9)

From the previous discussion regarding densities, it is clear that the radius of the gas envelope will be much greater than the core radius $R\gg {R}_{c}$ , so that (9) reduces to

${P}_{\mathrm{max}}=\frac{G{M}_{c}}{{R}_{c}}\rho \left(1+\frac{\rho}{2{\rho}_{c}}\frac{{R}^{2}}{{R}_{c}^{2}}\right)$ (10)

Since $\rho \ll {\rho}_{c}$ , it follows that $\rho {R}^{2}\ll 2{\rho}_{c}{R}_{c}^{2}$ for any reasonable black hole mass. This yields the formula

${P}_{\mathrm{max}}=\frac{G{M}_{c}}{{R}_{c}}\rho $ (11)

which will be used to determine the physical conditions near the core.

The pressure in the electron-positron gas is given by

${P}_{F}={\left(\frac{3{\text{\pi}}^{2}}{2}\right)}^{2/3}\frac{{\hslash}^{2}}{5m}{n}^{5/3}$ (12)

Equate this to (11) and set $\rho =nm$ to obtain

${\left(\frac{3{\text{\pi}}^{2}}{2}\right)}^{2/3}\frac{{\hslash}^{2}}{5m}{n}^{2/3}=\frac{G{M}_{c}m}{{R}_{c}}$ (13)

or

$n={5}^{1/2}\frac{10{m}^{3}}{3{\text{\pi}}^{2}{\hslash}^{3}}{\left(\frac{G{M}_{c}}{{R}_{c}}\right)}^{3/2}$ (14)

A neutron star core, with ${M}_{c}=1.5{M}_{\odot}$ and ${R}_{c}=1.1\times {10}^{6}\text{\hspace{0.17em}}\text{cm}$ , yields the number density for the lepton gas

$n=1.2\times {10}^{30}\text{\hspace{0.17em}}{\text{cm}}^{-3}$ (15)

and the mass density

$\rho =mn=1.1\times {10}^{3}\text{\hspace{0.17em}}\text{g}\cdot {\text{cm}}^{-3}$ (16)

Typical black hole dimensions are as follows: $M=5{M}_{\odot}$ , $R=1.1\times {10}^{10}\text{\hspace{0.17em}}\text{cm}$ ; $M=10{M}_{\odot}$ , $R=1.5\times {10}^{10}\text{\hspace{0.17em}}\text{cm}$ ; $M=20{M}_{\odot}$ , $R=2.0\times {10}^{10}\text{\hspace{0.17em}}\text{cm}$ . They are nearly the size of a normal star.

3. Remarks

Formula (14) shows that the density of the gas is determined by the intense gravitational field of the neutron star. It is little affected by the mass of the lepton gas itself. This results in a nearly common gas density for all stellar black holes. According to (11), the gas pressure near the core is
$2\times {10}^{22}\text{\hspace{0.17em}}\text{Pa}$ . As expected, this is much less than the pressure within the neutron star (10^{34} Pa).

The very thick cloud of leptons is a conductor of electricity. It would shield the magnetic field of the neutron star. Moreover, the cloud would absorb much of the angular momentum of the parent star, thereby reducing the neutron star’s rotation rate. In a more realistic treatment, the pressure and density would be related everywhere as in Formula (12), so that they both decrease with elevation. The resulting decrease in Fermi energy enables the upper layers of gas to interact with radiation coming from the core. During a collision with another black hole or neutron star, the lepton cloud could absorb a great deal of the electromagnetic radiation. Gravitational radiation would pass through the cloud unhindered.

Finally, it is worth emphasizing that the stellar black holes modeled here are those listed online [3] . They are not hypothetical. They are objects which have become paired with an observable star in a binary system. The astronomers have found that they have no magnetic field, they do not emit radiation, and they are always more massive than a neutron star. This model explains the experimental facts.

Note: The model treated here is incompressible. However, Formula (12) shows that the density of a degenerate gas varies with pressure. It is a polytrope, which satisfies the Lane-Emden equation [4] [5] . The standard Lane-Emden solution requires the initial condition dP/dr = 0 at the center. This condition cannot be met in the present case, because of the neutron star’s intense gravitational field near r = R_{c}. A new composite solution must be found, in order to improve upon the calculation given here.

Conflicts of Interest

The authors declare no conflicts of interest.

[1] | Landau, L. and Lifschitz, E. (1980) Statistical Physics Part 1. 3rd Edition, Pergamon, Section 57. |

[2] | Pathria, R. and Beale, P. (2011) Statistical Mechanics. 3rd Edition, Elsevier, Amsterdam, Chapter 8. |

[3] |
Stellar Black Hole. https://en.m.wikipedia.org |

[4] | Chandrasekhar, S. (1958) An Introduction to the Study of Stellar Structure. Dover, Chapter IV. |

[5] | Horedt, G.P. (2004) Polytropes. Kluwer, Alphen aan den Rijn, Section 2.1. |

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