Looking Outward, From Inside a Black Hole

[Written by J. E. Tohline, early morning of 13 October 2017] The relationship between the mass, $M$ , and radius, $R$ , of a black hole is,

$\frac{2 G M}{c^{2} R}$

$=$

$1 .$

The mean density of matter inside a black hole of mass $M$ is, therefore,

$\bar{ρ}$	$=$	$\frac{3 M}{4 π R^{3}} = \frac{3 M}{4 π} [\frac{2 G M}{c^{2}}]^{- 3} = \frac{3 c^{6}}{2^{5} π G^{3} M^{2}}$
	$\approx$	$[\frac{(3 \times 1 0^{10})^{6}}{2^{5} (\frac{2}{3} \times 1 0^{- 7})^{3} (2 \times 1 0^{33})^{2} M_{⊙}^{2}}] g {c m}^{- 3}$
	$\approx$	$[\frac{3^{6 + 3} \times 1 0^{60}}{2^{10} (1 0^{66 - 21}) M_{⊙}^{2}}] g {c m}^{- 3}$
	$\approx$	$[\frac{3^{9} \times 1 0^{60}}{2^{10} (1 0^{45}) M_{⊙}^{2}}] g {c m}^{- 3}$
	$\approx$	$[\frac{2 \times 1 0^{16}}{M_{⊙}^{2}}] g {c m}^{- 3} .$

We are accustomed to imagining that the interior of a black hole (BH) must be an exotic environment because a one solar-mass BH has a mean density that is on the order of, but larger than, the density of nuclear matter. From the above expression, however, we see that a $1 0^{9} M_{⊙}$ BH has a mean density that is less than that of water (1 gm/cm³). And the mean density of a BH having the mass of the entire universe must be very small indeed. This leads us to the following list of questions.

Enumerated Questions

Can we construct a Newtonian structure out of normal matter that has a mass of, say, $1 0^{9} M_{⊙}$ whose equilibrium radius is much less than the radius of the BH horizon associated with that object? Does it necessarily have a mean temperature whose associated sound speed is super-relativistic?
Who else in the published literature has explored questions along these lines?

Appendix/Ramblings/InsideOut

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Looking Outward, From Inside a Black Hole

Enumerated Questions

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Appendix/Ramblings/InsideOut

Looking Outward, From Inside a Black Hole

Enumerated Questions

See Also

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