If stars start with a finite density and light can escape from them, how can they be compacted to form a mass with infinite density which light cannot escape? The black hole will have the same mass as the original star (correct?) and therefore will act on the photons with the same force of gravity, right?


3 Answers 3


Gravity is not merely a function of mass, it also depends on how compact the matter is; you can deduce this from Newton's law of universal gravitation:

$$F = G\frac{m_1m_2}{r^2}$$

In layman terms, the more compact the body, the closer you can get to it without entering it, the smaller $r$ becomes, which makes the gravitational pull stronger.

I do not know enough to tell you about why a black hole has (or, is considered to have) infinite density, but since its mass is finite, its volume must tend towards zero for that to be true.

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    $\begingroup$ The infinite density thing comes about because general relativity predicts that all the mass of a black hole should eventually become concentrated at a single point in the center, the singularity. That might not actually be true, though, since general relativity may be inadequate to describe the center of a black hole. Perhaps a black hole actually has a finite density because of some unknown physics... but it is still a black hole, as long as all the mass fits inside the event horizon. $\endgroup$
    – David Z
    Commented Nov 28, 2011 at 2:06
  • $\begingroup$ @David: there is no argument that black holes have an infinite density center. They have to have a singularity, but the singularity can be as mild as a timelike cut-place where infocusing light becomes outfocusing (like in charged or rotating black holes). There is no evidence that matter is compressed to infinite density in the collapse, although if the matter isn't rotating, it will do this. $\endgroup$
    – Ron Maimon
    Commented Nov 28, 2011 at 2:40
  • $\begingroup$ @Ron: in GR, yes, they have to have a singularity. But one could take the singularity as a suggestion that GR is inadequate, and then the requirement for a singularity is up in the air. $\endgroup$
    – David Z
    Commented Nov 28, 2011 at 3:04
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    $\begingroup$ @David: In GR, there has to be a singularity, but it doesn't have to be at the center, it doesn't have to have infinite density, and no matter has to actually hit the singularity. There is no argument that says this, it is just one monkey parrotting another. The proof of the singularity theorems just requires that the incoming null geodesics need to hit some singular point where they defocus. Nothing other than null geodesics has to hit this point. Everything else is speculation by relativists, with an unfortunate consensus with no evidence. $\endgroup$
    – Ron Maimon
    Commented Nov 28, 2011 at 4:23
  • $\begingroup$ This blaming GR for that prediction of singularities is really parroting. GR does not know about any matter properties exept mass. So, in GR any gram or kg would be a point mass. Of course calculation of a star in GR includes its diameter, GR does not know about reasons for that. The existence of matter with extended dimensions is a question of QM. So, because we do not know about some repulsive force beyond the forces known today, some assume black holes are/develop singularities. But this is not a prediction of GR, it is a "we do not know something against it" from QM. $\endgroup$
    – Georg
    Commented Nov 28, 2011 at 10:29

@Paul is correct, the gravitational pull depends on the masses and the distance between the masses in Newtonian Gravity. To understand black holes, Einstein's General Theory of relativity needs to be used, but qualitatively you get the same result.

To get a stellar black hole, the star, or part of the star, must be compressed to a small enough radius such that the escape velocity at that surface exceeds the speed of light (this is a qualitative way of stating it, in reality the time-like future light cone becomes "rotated" into a spatial direction towards the interior of the star. The radius where this occurs is the Schwarzchild radius.

Once the surface of the star has contracted to inside the Schwarzchild radius it is inevitable that the star will continue to collapse to the center. Theoretically, at that point, all the mass would be concentrated to a point at the center of the black hole which would become a singularity. Physicists don't actually believe that infinite density will occur - the belief is that General Relativity will break down near the Planck radius and a different theory will be required.

What is required to have a black hole is not the "infinite" density, just that the stars mass be inside the Schwarzchild radius.


The black hole will have the same mass as the original star (correct?) and therefore will act on the photons with the same force of gravity, right?

Wrong but I know where the misconception is coming from. If you were at the Earth's orbit, the gravitational pull wouldn't change if the Sun were ten times bigger or smaller in radius. But if you were somewhere inside the Sun, it would.

Maybe think of it like this. Suppose you go to the radius of the Sun at which half the mass is inside. That would give some gravitational force. Now, imagine all of the Sun's mass were inside that radius. Then the gravitational pull would be stronger because you have more mass pulling at the same radius. In this sense, a more compact object has a stronger gravitational field, you just have to be close to the object to feel the difference.

You could go to much smaller radii. If you were just over 3km from the centre of the Sun, you wouldn't feel much gravity, because there would be very little mass inside. But if all the Sun's mass were confined to less than 3km, you'd be just above the event horizon of a black hole of one solar mass.

Black holes form basically by massive stars becoming incredibly compact, until their mass is confined inside their Schwarzschild radii. Light can still escape from where the surface used to be, but very close in, it can't.

Also, the infinite density point isn't important. This all happens as long as the mass is confined to less than its Schwarzschild radius. We can't see "inside" the black hole, so we don't know what happens to the matter inside. Fortunately, it also doesn't matter for the exterior gravitational field.


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