All things aside, how big could a black hole actually get?

In summary: Second, the idea of an infinite universe at the same density as observed is not supported by evidence. The evidence suggests that the universe is finite and has a finite size. Third, your claims about the dynamics of objects are not supported by evidence either. There is no evidence that objects behave differently around a black hole compared to any other mass.
  • #1
Lunar-Scooter
4
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Say if one were to meet a nice little black hole and just feed it, everything one could throw at it...

Galaxies, other black holes, just everything... how BIG could it actually get, before things started to not be so "black holeish" - like the gravity started to weaken or light started to escape etc., or would it just grow and grow more intense, only with a bigger size.
 
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  • #2
It would just grow and increase its mass and size. While some effects like spaghettification get smaller, it stays a black hole.
 
  • #3
50 billion suns could be lurking out there - but that's the limit.
http://www.newscientist.com/article/dn14653-how-big-can-a-black-hole-grow.html

Two astronmers reached that conclusion. But the reasons provided have nothing to do with any internal inability to become bigger. Instead, they are based on the limiting factors that the black hole creates in its own vicinity via blasting away available additional material until it sits starved of new matter. Barring that there seems to be no reason why there should be a limit. In fact, The Big Crunch Theory of how the universe could end had all matter in the unviverse collapsing into a singularity or black hole.
 
  • #4
I think this limit could be exceeded via feeding with controlled angular momentum. In that case, the matter would just fall into the black hole, without forming an accreation disk.
 
  • #5
mfb said:
I think this limit could be exceeded via feeding with controlled angular momentum. In that case, the matter would just fall into the black hole, without forming an accreation disk.

As pointed out, the limit is based on the observation of how a black hole clears out the immediate vicinity until there isn't any more material available to consume. Also, control takes the situation out of the natural phenomenon category into the speculative or what-if of sci fi. To bring in a hypothetical situation where the natural process isn’t present because someone is control-feeding the black hole might be useful for a Sci Fi story. But on a forum that limits itself to reality, it is really out of place.
 
  • #6
Radrook said:
As pointed out, the limit is based on the observation of how a black hole clears out the immediate vicinity until there isn't any more material available to consume.
Your statement seems to suggest that black holes work like vacuum cleaners.

That is not the case, it is actually hard to fall into a black hole, it is far more likely one zooms past it or orbits one (or more) times and travels away.

From the perspective of the dynamics of objects there are no differences between a black hole and any other mass.
 
  • #7
I think a more interesting question is, what is the maximum size the universe could be, at its observed density, without becoming a black hole?
 
  • #8
skeptic2 said:
I think a more interesting question is, what is the maximum size the universe could be, at its observed density, without becoming a black hole?
That would require the universe to have a center of gravity (think balloon and dots, no single dot is in the center).
 
  • #9
The balloon and dots represents a closed universe. Even a closed universe without a center of gravity and without dark energy should contract under its own gravity.

I think our best measurements indicate the universe is flat or open. Could an infinite universe at the same density we observe exist?
 
  • #10
Passionflower said:
Your statement seems to suggest that black holes work like vacuum cleaners.

That is not the case, it is actually hard to fall into a black hole, it is far more likely one zooms past it or orbits one (or more) times and travels away.

From the perspective of the dynamics of objects there are no differences between a black hole and any other mass.

The likelihood of falling into a black hole has nothing to do with the question that was asked. Neither does the differences between a black hole and any other mass.

The question is limited to how large a black hole is able to become and I limited my response to that question.

Your comments might be relevant in response to the issues you have added but are off topic to this one in my opinion.

In any case, let's momentarily consider your claims.

First, the analogy between a black hole and a vacuum cleaner is inappropriate because the attempted comparison would break down in too many places due to the obvious dissimilarity of the twain. Clearly a vacuum cleaner isn't interacting with objects in motion that might resist being pulled in or go into orbit around it. A vacuum cleaner doesn't attract from all directions as a black hole does. Things that are drawn in don't undergo the same transformations. It doesn't spaghettify things, for example. The vacuum cleaner itself isn't in either orbital motion or rapidly spinning on its axis. So even if we imagine it as a planet sized vacuum cleaner the forces involved and the dynamics just do not mesh.Second, your statement seems to imply that it is always difficult to fall into a black hole. That seems to contradict your other statement that in terms of mass and gravity black holes do not differ from any other massive objects. Whether or not it is hard to fall into a black hole, of course, would depend on trajectory and velocity and mass as it would with any other celestial body of significant mass.

Your statement that black holes are essentially no different from other massive bodies is also misleading since most mass isn't as densely compressed as it is in a black hole and neither are singularities found within non-black-hole masses. In fact, that's what makes study of black holes so interesting, their difference from regular celestial objects, a difference which you seem to claim to be virtually almost non-existent.

Third, at present our knowledge of what happens to matter once it reaches that singularity is completely absent because the laws of physics break down at that point. So no, I am not comparing a black hole to a vacuum cleaner. The comparison simply breaks down in too many places to function as an effective analogy.BTW

I think you misunderstod the expression "clearing out" as a vacuming action. The clearing out also involves the blasting away of surrounding material caused by the black hole's activitiies. It is briefely mentioned in the article provided.
 
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  • #11
The case remains that a black hole is no different than any other gravitating mass. Unless you are near the event horizon it is indistinguishable from any other equally massive body.
 
  • #12
What about a diffuse, yet very, very very large gas cloud that exists within itself Schwarzschild radius? As I have read before, those were the precursors of supermassive black holes in the early universe.

What limited their size to a few million solar masses? Why not an arbitrarily large diffuse gas cloud? In fact, just intuitively speaking it should be even easier to have billion, or trillion solar mass clouds, as Schwarzschild radius increases to proportionally to the mass but the actual radius only increases proportional to the cube root of mass.
 
  • #13
Chronos said:
The case remains that a black hole is no different than any other gravitating mass. Unless you are near the event horizon it is indistinguishable from any other equally massive body.

Please show me where I said it was gravitationally different in my original response to this question.
 
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  • #14
Radrook said:
Please show me where I said it was gravitationally different in my original response to this question.

deleted
 
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  • #15
chill_factor said:
What about a diffuse, yet very, very very large gas cloud that exists within itself Schwarzschild radius? As I have read before, those were the precursors of supermassive black holes in the early universe.

What limited their size to a few million solar masses? Why not an arbitrarily large diffuse gas cloud? In fact, just intuitively speaking it should be even easier to have billion, or trillion solar mass clouds, as Schwarzschild radius increases to proportionally to the mass but the actual radius only increases proportional to the cube root of mass.
deleted
 
  • #16
chill_factor said:
What about a diffuse, yet very, very very large gas cloud that exists within itself Schwarzschild radius? As I have read before, those were the precursors of supermassive black holes in the early universe.
Not dense enough without some massive attraction in the center, e.g. the remnants of early stars, which fused to a black hole of significant size.


Radrook said:
Also, control takes the situation out of the natural phenomenon category into the speculative or what-if of sci fi. To bring in a hypothetical situation where the natural process isn’t present because someone is control-feeding the black hole might be useful for a Sci Fi story. But on a forum that limits itself to reality, it is really out of place.
Lunar-Scooter said:
Say if one were to meet a nice little black hole and just feed it, everything one could throw at it...
Talking about a fed black hole is like talking about relativistic trains: It is a method to explore science, without performing actual experiments (because we don't have access to relativistic trains or black holes to perform experiments with).
 
  • #17
Very true. My apologies. Hypotheticals are definitely useful. But the fact remains that there isn't anything that indicates that such a fed black hole has a limit to what it can devour. However, the Big Crunch Theory seems to make room for it by postulating a cyclical universe. But that rebound is purely conjecture and not based on the laws of physics as we know them.

Big Crunch
http://science.howstuffworks.com/dictionary/astronomy-terms/big-crunch.htm

Note please that in this scenario the universe becomes a singularity. Which seems to support the idea that at a certain point in feeding a black hole it will rebound with a big bang.
 
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  • #18
Radrook said:
Note please that in this scenario the universe becomes a singularity. Which seems to support the idea that at a certain point in feeding a black hole it will rebound with a big bang.

I do not understand this logic at all. If some quantum gravitational correction produces some bounce near the singularity of a big crunch, the mechanism should work equally well for any mass. That is, it would resolve the singularity of any size black hole into a non-singular object. Even so, it seems very difficult to escape that there still must exist an event horizon, and there is no reason to suppose that this disappears at any particular size.
 
  • #19
Nabeshin said:
I do not understand this logic at all. If some quantum gravitational correction produces some bounce near the singularity of a big crunch, the mechanism should work equally well for any mass. That is, it would resolve the singularity of any size black hole into a non-singular object. Even so, it seems very difficult to escape that there still must exist an event horizon, and there is no reason to suppose that this disappears at any particular size.

Please show me where I said that the event horizon disappears.
 
  • #20
Radrook said:
Please show me where I said that the event horizon disappears.

Well you did not, you said that there would be a 'big bang'. I simply assumed this meant the structure of the hole, i.e. the horizon, would be eliminated by this. What did you mean, then?
 
  • #21
Nabeshin said:
Well you did not, you said that there would be a 'big bang'. I simply assumed this meant the structure of the hole, i.e. the horizon, would be eliminated by this. What did you mean, then?
As you already know, the Big Crunch theory postulated that universal expansion following the BB halts, matter reverses direction, collapses into a singularity and another Big Band occurs ad infinitum The mechanism behind this they did not know but simply tossed the idea around as feasible.

As the black hole caused by the crunch grew its event horizon would expand to gargantuan dimensions thus accelerating the influx of material. Eventually all matter would be inexorably drawn in regardless of where that matter is located. Ultimately the whole infernal thing would collapse back into the infinitely small primordial cosmic egg that it had been and somehow Big Bang all over again.

But since infinitely dense and infinitely-small singularities are described as retaining and event horizons, then the question is, now that YOU mention it, whether this one would also.

Please note that this singularity involves not only the collapse of matter but of space time itself leaving nowhere to extend an event horizon into. If indeed we imagine that an event horizon remains, then we would be forced to explain just where such a horizon would be extending into since space has disappeared into the singularity. This is totally unlike the regular singularities where the surrounding universe remains intact leaving a place where an event horizon can indeed manifest itself.

So since the question is whether a fed black hole can ever reach a point where it rebounds or regurgitates, and a black hole harbors a singularity, then this Big Crunch or Oscillating universe theory seems to indicate that it might. That is unless the qualitative difference between it and a regular infinitely small singularity makes the conclusion untenable which very well might be the case.
 
  • #22
When you attempt to apply the laws of thermodynamics to a cyclical universe model, you are immediately confronted with serious issues.
 
  • #23
Chronos said:
When you attempt to apply the laws of thermodynamics to a cyclical universe model, you are immediately confronted with serious issues.

I am not personally attempting nor proposing anything. In any case, can you please be more specific.
 
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  • #24
When you propose a cyclical universe, you inherit the burden of explaining how it conforms to the laws of thermodynamics.
 
  • #25
Chronos said:
When you propose a cyclical universe, you inherit the burden of explaining how it conforms to the laws of thermodynamics.

In other words, you see burdensome thermodynamics problems inherent in the once-proposed cyclical-universe idea.
 
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  • #27
You don't need to have a big crunch in principle do you?

If all the matter (dark and light) and energy (dark and light) in the universe (best guess of course as to the quantity) were dropped into one black hole, what would be the radius of the event horizon?

I estimate (without having done the math) about 1 galactic radius.
 
  • #28
Antiphon said:
You don't need to have a big crunch in principle do you?
Cyclic models such as the Big Crunch demand that the cycles be infinite. But that in turn requires that we deal with the problem of heat death caused by entropy. In fact, that original cyclic model was discarded exactly because of it since heat death would bring the oscillations to a halt. But other cyclic models such as the Steinhardt–Turok model and The Baum–Frampton model are considered more feasible by some because they evade the heat death scenario in various ways. However, they too create problems that elude a theoretical solution. In any case, at present evidence indicates that expansion is accelerating while deceleration and reversal have no such observational support.

Cyclic Models
http://en.wikipedia.org/wiki/Cyclic_model
If all the matter (dark and light) and energy (dark and light) in the universe (best guess of course as to the quantity) were dropped into one black hole, what would be the radius of the event horizon?

I estimate (without having done the math) about 1 galactic radius.

Interesting estimate. Did you include the undetectable part of the universe? By undetectable I mean the part that is beyond detection due to the universal expansion.
 
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1. What determines the maximum size a black hole can reach?

The maximum size of a black hole is determined by its mass. As a black hole gains more mass, its gravitational pull becomes stronger and it can grow larger. However, there is a limit to how much mass a black hole can hold before it reaches a point of instability.

2. Is there a limit to how big a black hole can grow?

Yes, there is a limit to how big a black hole can grow. This is known as the Chandrasekhar limit, which is approximately 1.4 times the mass of the sun. If a black hole were to exceed this limit, it would become unstable and eventually explode.

3. Can a black hole continue to grow indefinitely?

No, a black hole cannot continue to grow indefinitely. As it gains more mass, it also emits Hawking radiation, which causes it to lose mass over time. This process becomes more significant as the black hole grows larger, eventually causing it to shrink and potentially evaporate.

4. Are there any known black holes that have reached their maximum size?

There are no known black holes that have reached their maximum size. However, there are supermassive black holes at the centers of galaxies that are estimated to be billions of times the mass of our sun. These black holes are still growing and may continue to do so until they reach the Chandrasekhar limit.

5. How big could a black hole theoretically get?

In theory, a black hole could continue to grow until it consumes the entire universe. However, this is highly unlikely as the universe is constantly expanding and the rate of black hole growth is limited by the amount of mass and energy available. It is also possible that other factors, such as the eventual evaporation of black holes, could prevent them from reaching infinite size.

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