Can Black Holes Truly 'Grow' in the Lifetime of the Universe?

In summary, the concept of black holes growing in size is often equated with their Schwarzschild radius or event horizon increasing as they consume external matter. However, from the perspective of distant observers, matter falling into a black hole can never actually reach the event horizon within the lifetime of the universe. This is due to the fact that light signals from events at or inside the event horizon can never escape to reach distant observers. Despite this limitation, black holes can still be observed to grow in mass, as evidenced by the increase in gravitational pull felt by distant observers. This growth is not directly observable by distant observers, as their natural time coordinate cannot describe the spacetime at and inside the event horizon. However, this does not mean that the spacetime
  • #71
Yes, Peter, I understand that. But I am accused of claiming that events on my light cone are simultaneous, and I have never claimed any such silly thing.

Of course events that occur at the same time and place are simultaneous, and this is so obvious that no-one bothers to discuss it. Thats why the scientists only discuss it for spatially separated events, in which case it all depends on the reference frame.

Mike
 
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  • #72
Mike Holland said:
Yes, Peter, I understand that. But I am accused of claiming that events on my light cone are simultaneous, and I have never claimed any such silly thing.

If you didn't intend to make such a claim, then DaleSpam is not the only one who finds your use of language to be, at the very least, confusing. I do as well.

Mike Holland said:
Of course events that occur at the same time and place are simultaneous, and this is so obvious that no-one bothers to discuss it. Thats why the scientists only discuss it for spatially separated events, in which case it all depends on the reference frame.

It's good that you recognize that, but it wasn't obvious from your prior posts. Let me suggest a better way of wording what I think you may be trying to say:

The past light cone of the event "here and now" defines one *boundary* of our "now"; only events to the future of that boundary are candidates to be considered as part of our "now" (which specific events outside the boundary count as our "now" depends on the simultaneity convention we adopt). Similarly, the future light cone of the event "here and now" defines the other boundary of our "now"; only events to the past of that boundary are candidates to be considered as part of our "now". The standard Einstein simultaneity convention picks the set of events that are exactly "halfway between" these two boundaries as "now", but other conventions are possible, as long as they are consistent with the boundary requirements above.
 
  • #73
Mike Holland said:
I am referring to the coordinate system we use all the time in our everyday lives. We observe a supernova, and say that it occurred in 2012. In this everyday sense it was simultaneous with our calendars reading 2012. But as it is 1000 LY away, we calculate that it "really" occurred in 1012. Someone passing by at 0.83c might say it is 500 LY away, and occurred in 1512. [..]
Ah, that's a little different. Some people may mean with "supernova" the phenomenon as seen on Earth, and which we ascribe to something that happened a long time ago. In scientific discussions we only say that Sirius exists because we know of no reason to assume that something happened to it during the last 10 years; we don't mean with "Sirius exists" that we observe it now.

However, the confusion between the time of observation here and the time of occurrence there is itself a recurring phenomenon in recent discussions; hopefully it will be settled in the thread on simultaneity.
 
  • #74
PAllen said:
In case it isn't clear, what Dalespam is complaining about is that while there simultaneity is very much a matter of convention, it is universally accepted that the one restriction is that you don't consider causally connected events to be simultaneous. You have to pick between your forward and backward light cones. Einstein's convention basically takes exactly half way between for SR.

As a side issue, this is also why I am not happy with PeterDonis referring to the whole region between light cones as "now". All events there are certainly candidates for "now", but you need to select them by selecting a coordinate system to describe this region which you cannot view. I cannot accept the idea of causally connected events there all being referred to as "now". Not for one particular observer, anyway.

But this isn't physics. It is just the use of language.

Mike
 
  • #75
Mike Holland said:
As a side issue, this is also why I am not happy with PeterDonis referring to the whole region between light cones as "now".

I actually did make an argument along those lines once, but it wasn't in this thread. For this discussion I agree that "now" refers to a particular surface of simultaneity, not to the entire region between the light cones.

Mike Holland said:
I cannot accept the idea of causally connected events there all being referred to as "now".

This is a good point which I hadn't considered when I made the comments in the earlier thread I referred to above. One requirement of any reasonable concept of "now" should be that no two events in the set we label "now" can be causally connected. That makes it untenable to view the entire set of events between the light cones as "now". None of the events in that set are causally connected to the event "here and now", but there are certainly events in that set which are causally connected to each other.
 
  • #76
I have been following the discussions above, and somehow it has given rise to a new question in my mind:

  • How did the concept of 'black holes' come up in the first place from GR, from a historical perspective? Was it the Schwarzschild solution/metric that gave rise to this concept? Or, was it something different?

I believe Einstein never quite accepted this particular corollary of GR, and he was not necessarily right in doing so. All the development of black hole theory seems to be post-Einstein or extra-Einstein...

Any insights on this will be very helpful, especially if there is a chronology of the development of this.
 
  • #77
arindamsinha said:
  • How did the concept of 'black holes' come up in the first place from GR, from a historical perspective? Was it the Schwarzschild solution/metric that gave rise to this concept? Or, was it something different?

...

Any insights on this will be very helpful, especially if there is a chronology of the development of this.

A good layman's chronology, from someone in the field, is in Kip Thorne's popular book Black Holes and Time Warps. Going from memory since I don't have my copy handy, a quick chronology would, I think, look something like this (some of these items may only be mentioned very briefly, if at all, in the book, but this stuff has come up in a number of recent threads so it's fresh in my mind :wink:):

1915: Einstein publishes his field equation.

1916: Schwarzschild discovers his solution, but he writes it in coordinates in which what we now know as the event horizon is at "r" = 0, not r = 2M. Consequently, he only discusses one region of the solution, whereas we now know (see below) that there are others as well.

1920's or early 30's: I believe Eddington, sometime during this period, came up with at least a version of what we now call Eddington-Finkelstein coordinates, but there was no follow-up for several decades. Also, sometime during this period, what we now call Painleve or Lemaitre coordinates were independently invented several times, but again there was no follow-up for several decades.

1939: Oppenheimer and Snyder publish their paper on gravitational collapse: first known model that includes collapsing matter and the vacuum region around it. However, they write their model in what we now call Schwarzschild exterior coordinates (*not* the same coordinates that Schwarzschild himself used in his 1916 paper!), and the physical nature of the coordinate singularity at the horizon (r = 2M) is not fully understood.

1939: Einstein publishes a paper showing that no stationary configuration of matter can be in a stable equilibrium unless its radius is at least 9/4 M (i.e., at least 9/8 of the Schwarzschild radius corresponding to its mass). He believes that this shows that gravitational collapse cannot occur; our modern understanding is that it only shows that a collapsing object, such as the one that appears in the Oppenheimer-Snyder paper, can't be in a stable equilibrium once its radius is less than 9/4 M.

1957: Finkelstein publishes a paper deriving what we now call Eddington-Finkelstein coordinates, and arguing that his derivation shows that the Schwarzschild solution to the Einstein Field Equation must include a region inside the event horizon, because otherwise the solution is incomplete: geodesics reach the horizon in a finite proper time, and all physical invariants are finite there, so they can't just stop without violating the EFE.

1960: Kruskal discovers that the full, maximally extended Schwarzschild solution contains even *more* regions than Finkelstein had thought: a total of four. Two of these (exterior, and black hole interior) are those covered by Eddington-Finkelstein (and Painleve) coordinates. However, Kruskal shows, by the same sorts of arguments that Finkelstein used, that in the (idealized and not physically reasonable, according to the best current understanding) case of a spherically symmetric spacetime which is vacuum everywhere, the solution is incomplete unless a "white hole" region and a *second* exterior region are also added. (These regions do *not* appear in solutions such as the Oppenheimer-Snyder model when those solutions are completed; instead, portions of regions I and II are joined to a non-vacuum region containing the collapsing matter.)

1960's: The "golden age" of black hole research: new mathematical tools are developed to study the global properties of spacetimes (i.e., solutions to the EFE), and various singularity theorems are proved which show that, if classical GR is correct, gravitational collapse starting from some reasonable initial conditions *must* form an event horizon, a black hole, and a curvature singularity at r = 0. After this point the study of black holes became "mainstream" relativity physics.
 
  • #78
arindamsinha said:
I have been following the discussions above, and somehow it has given rise to a new question in my mind:

  • How did the concept of 'black holes' come up in the first place from GR, from a historical perspective? Was it the Schwarzschild solution/metric that gave rise to this concept? Or, was it something different?

I believe Einstein never quite accepted this particular corollary of GR, and he was not necessarily right in doing so. All the development of black hole theory seems to be post-Einstein or extra-Einstein...

Any insights on this will be very helpful, especially if there is a chronology of the development of this.

Here is a rough chronology:

http://en.wikipedia.org/wiki/Timeline_of_black_hole_physics

Plenty is missing, co-discoverers, and earlier discoverers often absent, but a reasonable high level chronology.

Yes, Einstein never accepted that BH could actually form (he did not reject that they were solutions of GR). However, since all of Penrose and Hawking's work that really established they could and would form if GR is true came after his death, that isn't saying much.
 
  • #79
PeterDonis and PAllen,

This is great stuff. Thanks for the responses. This is very helpful.

One more question this raises - does this mean that the original Schwarzschild solution/metric:

1/√(1-2GM/Rc2 - v2/c2 - ...) or the c22 = ...

is no longer considered completely adequate, and has been superceded by later work?

I believe the Schwarzschild solution is still used often, and describes some observed time dilation phenomena nicely (e.g. GPS satellites). Have there been further developments/refinements to this metric, and if so, would you be able to provide some inputs on that? Looking for something of low mathematical complexity that I can understand, not something marinated in tensors etc. hopefully :smile:)
 
  • #80
This is very interesting indeed. :-)

In view of the history I distinguish different "flavours" of GR:

- 1916 GR. Acceleration is truly "relative", and can be explained away by "induced gravitational fields". This was the driving force behind GR and it gave GR its name.
- Early GR, or Einstein's GR. Even Einstein seems to have abandoned 1916 GR; however he stuck to the remainder, incl. the physical reality of gravitational fields.
- Modern GR. It proposes the falling of matter inside R of black holes as well as the existence of white holes.

However, modern GR is only partially accepted: white holes are found to violate thermodynamics (says Hamilton; I never looked at that). And the falling of matter inside R violates quantum mechanics.

PS looking at the development like this from a distance, it appears that an equation has been pushed beyond its limits. :wink:
 
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  • #81
harrylin said:
- Modern GR. It proposes the falling of matter inside R of black holes

Yes.

harrylin said:
as well as the existence of white holes.

No. "Modern GR" does not consider white holes to be physically reasonable. They are valid mathematical solutions of the EFE only if the spacetime is vacuum everywhere. Nobody believes that this mathematical solution describes any actual, physical spacetime. Any actual, physical spacetime contains matter somewhere; in the case of a collapsing object that forms a black hole, the spacetime obviously contains matter.

Every equation in any physical theory has solutions that aren't physically reasonable; as PAllen and I have pointed out in the other thread that's running on this topic, and as you agreed there, you have to add additional constraints to determine which mathematical solutions are physically reasonable. If you are going to make claims about what "modern GR" says, at least make them about what the full theory, including constraints as well as mathematical solutions to equations, actually says.

harrylin said:
However, modern GR is only partially accepted

Not true. Please do not make these kinds of claims when you don't fully understand what "modern GR" says.

harrylin said:
white holes are found to violate thermodynamics

Yes, which is one major reason why nobody thinks the mathematical solutions describing white holes are physically reasonable.

harrylin said:
And the falling of matter inside R violates quantum mechanics.

No, that part doesn't violate QM. The part that violates QM is when the quantum states reach the singularity at r = 0 and are destroyed. That violates unitarity. But just falling inside the horizon does not.
 
  • #82
PeterDonis said:
[..] No. "Modern GR" does not consider white holes to be physically reasonable. They are valid mathematical solutions of the EFE only if the spacetime is vacuum everywhere. [..]
You give a different different reason than Hamilton; I can't judge that now.
- http://casa.colorado.edu/~ajsh/schww.html
No, [just falling inside the horizon] doesn't violate QM.
Oops indeed, thanks for the correction!
 
  • #83
harrylin said:
You give a different different reason than Hamilton

Sorry, I should have clarified: I didn't mean to suggest that I thought Hamilton's reason didn't apply as well. Both what he says (white holes violate the second law of thermodynamics) and what I said (white holes are only present in the solution of the EFE if the spacetime is vacuum everywhere) are correct, and either one by itself would, IMO, be a good reason not to consider white holes physically reasonable. Both of them taken together just make the argument stronger.
 
  • #84
PeterDonis said:
Sorry, I should have clarified: I didn't mean to suggest that I thought Hamilton's reason didn't apply as well. Both what he says (white holes violate the second law of thermodynamics) and what I said (white holes are only present in the solution of the EFE if the spacetime is vacuum everywhere) are correct, and either one by itself would, IMO, be a good reason not to consider white holes physically reasonable. Both of them taken together just make the argument stronger.
Yes; I'm just surprised that there he doesn't mention that other reason, which looks more pertinent to me.
 
<h2>1. How do black holes grow in the lifetime of the universe?</h2><p>Black holes grow through a process called accretion, where they pull in surrounding matter such as gas and stars. As the matter gets closer to the black hole, it speeds up and releases large amounts of energy, causing the black hole to grow in mass.</p><h2>2. Can black holes grow infinitely?</h2><p>According to current theories, black holes can continue to grow as long as there is matter available for them to accrete. However, there are limits to how large they can grow, as there is a maximum size for a black hole known as the Schwarzschild radius.</p><h2>3. How fast do black holes grow?</h2><p>The rate of growth for a black hole depends on the amount of matter available for accretion and the size of the black hole itself. Supermassive black holes at the center of galaxies can grow at a rate of millions of times the mass of our sun per year, while smaller black holes may grow at a slower rate.</p><h2>4. Can black holes merge and grow even larger?</h2><p>Yes, when two black holes come close enough to each other, they can merge and form a larger black hole. This process is known as a black hole merger and has been observed through the detection of gravitational waves.</p><h2>5. Is there a limit to how many black holes can exist in the universe?</h2><p>The number of black holes in the universe is currently unknown, but it is believed that there is a finite amount. As black holes continue to grow and merge, they may eventually reach a point where they are too large to merge with any other black holes, limiting the number of black holes in the universe.</p>

1. How do black holes grow in the lifetime of the universe?

Black holes grow through a process called accretion, where they pull in surrounding matter such as gas and stars. As the matter gets closer to the black hole, it speeds up and releases large amounts of energy, causing the black hole to grow in mass.

2. Can black holes grow infinitely?

According to current theories, black holes can continue to grow as long as there is matter available for them to accrete. However, there are limits to how large they can grow, as there is a maximum size for a black hole known as the Schwarzschild radius.

3. How fast do black holes grow?

The rate of growth for a black hole depends on the amount of matter available for accretion and the size of the black hole itself. Supermassive black holes at the center of galaxies can grow at a rate of millions of times the mass of our sun per year, while smaller black holes may grow at a slower rate.

4. Can black holes merge and grow even larger?

Yes, when two black holes come close enough to each other, they can merge and form a larger black hole. This process is known as a black hole merger and has been observed through the detection of gravitational waves.

5. Is there a limit to how many black holes can exist in the universe?

The number of black holes in the universe is currently unknown, but it is believed that there is a finite amount. As black holes continue to grow and merge, they may eventually reach a point where they are too large to merge with any other black holes, limiting the number of black holes in the universe.

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