Black hole matter accumulation

In summary, the formation of a black hole is determined by the ratio between the area occupied and the area representing its mass, with the critical point being when the ratio is smaller than 4. This results in the object's occupied area shrinking to zero and becoming an inescapable black hole. The mass of the black hole is not directly related to its size, and it is possible for a black hole to have less mass than a huge star. As the mass accumulates, time slows down from the perspective of an outside observer, but from the perspective of matter flowing into the singularity, time flows normally. The formation of a black hole is usually rapid and is caused by a super nova explosion or the collapse of a giant star.
  • #1
keepit
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0
a black hole is first large object until it has enough mass to make it inescapable. Once the black hole accumulates the amount of mass to make it inescapable, doesn't time stop down for that mass that keeps accumulating after that point?
 
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  • #2
Whether something is a black hole not has nothing to do with the mass. The mass of a grain of salt could be a black hole as well.

Actually the amount of matter is not relevant, it is the ratio between area and mass that matters.

A non-spinning object becomes (or is already) a black hole if the ratio between the area it occupies and the area that represents its mass is smaller than 4. As soon as this happens the object's occupied area will shrink to zero.

E.g.:

[tex]
{A_{occupied} \over A_{mass} } < 4
[/tex]
 
  • #3
Passionflower, you may want to clearly define "area occupied" since most people will think in terms of "volume occupied".
 
  • #4
DaleSpam said:
Passionflower, you may want to clearly define "area occupied" since most people will think in terms of "volume occupied".
Actually I think it is simpler to express it in terms of area as volume is not Euclidean in curved spacetime and it avoids the usage of the r coordinate which is not a measure of distance in Schwarszschild coordinates.

For instance the volume occupied from the EH down to the singularity is actually infinite so that is not very helpful.
 
  • #5
Passionflower said:
Actually I think it is simpler to express it in terms of area as volume is not Euclidean in curved spacetime and it avoids the usage of the r coordinate which is not a measure of distance in Schwarszschild coordinates.
I agree it is simpler, but you still should explain what it means for a mass to occupy an area just for clarity. Most new posters will not know what you mean.
 
  • #6
keepit said:
a black hole is first large object until it has enough mass to make it inescapable. Once the black hole accumulates the amount of mass to make it inescapable, doesn't time stop down for that mass that keeps accumulating after that point?

black hole and time stopping are far off . time stops relative to things outside it. And center of a black hole is a point of infinite density and zero volume . mass has to do with the size of black hole . it doesn't acquire mass it shrinks to zero volume making everything inescapable.
 
  • #7
Rishavutkarsh said:
black hole and time stopping are far off . time stops relative to things outside it. And center of a black hole is a point of infinite density and zero volume . mass has to do with the size of black hole . it doesn't acquire mass it shrinks to zero volume making everything inescapable.

Kerr black holes have ring singularities which do not have zero volume.
 
  • #8
WannabeNewton said:
Kerr black holes have ring singularities which do not have zero volume.
Are you sure about that? I thought that ring singularities were 1 dimensional. So they would have a circumference, but no volume. But I admit that I have not studied the Kerr solution in as much detail as I should have.
 
  • #9
DaleSpam said:
Are you sure about that? I thought that ring singularities were 1 dimensional. So they would have a circumference, but no volume. But I admit that I have not studied the Kerr solution in as much detail as I should have.

Yeah you're right I confused the two. Its basically the outer equator of a torus, so no volume.
 
  • #10
But some black holes have less mass than those huge stars, you might have some misunderstanding.

And what do you mean by "time stop down for that mass"?
 
  • #11
Zeal,
I didn't state my question very well. Rather than say "When a mass gets big enough" i should have said "when a mass qualifies as a black hole". sorry.
Anyhow i was just trying to understand better what is going on with the mass as it goes from not being a black hole to being a black hole. I guess time slows down gradually for the mass as it accumulates. Correct me if I'm wrong.
Thank you.
 
  • #12
The time slowing/stopping is from the perspective of the outside observer. For matter flowing into the singularlity time flows from its perspective as normal.
 
  • #13
keepit said:
Zeal,
I didn't state my question very well. Rather than say "When a mass gets big enough" i should have said "when a mass qualifies as a black hole". sorry.
Anyhow i was just trying to understand better what is going on with the mass as it goes from not being a black hole to being a black hole. I guess time slows down gradually for the mass as it accumulates. Correct me if I'm wrong.
Thank you.

I think that going from normal stars to black holes is usually very rapid, which involves super nova explosion or collapse of giant stars. Using the Schwarzschild black hole as the simplest model, you can see that it is the radius that matters. To my perspective, if the radius of the event horizon is smaller than that of the star, it would not be a black hole. But usually collapse of stars and super nova explosion cause these rapid decrease of radius.
 
  • #14
Gravitation potential becomes lower as we go toward center of mass. Because of that event horizon should first form at the center of gravitating body that is going to turn into the black hole and then move outward. I believe that is the way how birth of BH is modeled.

But at the center of gravitating body mass is not falling anywhere. So it should be extremely time dilated right before it turns into the black hole. So from where this "seed" black hole appears at the center of the body?
 
  • #15
keepit said:
Zeal,
I didn't state my question very well. Rather than say "When a mass gets big enough" i should have said "when a mass qualifies as a black hole". sorry.
Anyhow i was just trying to understand better what is going on with the mass as it goes from not being a black hole to being a black hole. I guess time slows down gradually for the mass as it accumulates. Correct me if I'm wrong.
Thank you.

You might find the following post (and the thread) from https://www.physicsforums.com/showthread.php?t=473047" of interest (Note: M=Gm/c2)-

stevebd1 said:
I think some insight can be gained from looking at the Schwarzschild interior metric. If we consider the time component only-

[tex]d\tau=\left( \frac{3}{2}\sqrt{1-\frac{2M}{r_0}}-\frac{1}{2}\sqrt{1-\frac{2Mr^{2}}{r_0^{3}}}\right)dt[/tex]

where r0 is the radius of the spherical mass. If we consider a neutron star that has exceeded the TOV limit at 3 sol mass through accretion, r0 will gradually reduce*. Considering M being a constant and r0 reducing, when r0 reaches 9M/4, [itex]d\tau[/itex] at r=0 (i.e. the centre of the neutron star) becomes zero. As r0 becomes less than 9M/4, a radius where [itex]d\tau=0[/itex] begins to move outwards from the centre, any volume of space within this radius is spacelike and because there are no stable radii in spacelike spacetime, this will induce the collapse of matter within to a form of singularity. This radius where [itex]d\tau=0[/itex] will continue to move outwards as r0 reduces until they both meet at 2M and the interior solution becomes the vacuum solution.

*It's worth noting that in GR, pressure contributes to the stress energy tensor so the more compact a neutron star becomes, the greater the gravity.
 
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  • #16
stevebd1 said:
If we consider a neutron star that has exceeded the TOV limit at 3 sol mass through accretion, r0 will gradually reduce*.
*It's worth noting that in GR, pressure contributes to the stress energy tensor so the more compact a neutron star becomes, the greater the gravity.
And why exactly r0 will be gradually reduced?
To me it seems the other way around - that r0 should gradually increase. First, additional matter occupies some place and second, kinetic energy of accreted matter is converted into heat that would tend to expand the body.
 
  • #17
zonde said:
And why exactly r0 will be gradually reduced?
To me it seems the other way around - that r0 should gradually increase. First, additional matter occupies some place and second, kinetic energy of accreted matter is converted into heat that would tend to expand the body.

The kinetic energy would convert into pressure (sometimes, pressure is described as confined KE) and Einstein's algebraic equation for gravity is [itex]g=\rho+3P[/itex] where [itex]\rho[/itex] is density and P is pressure and so the gravity would increase, pulling the star in on itself.
 
  • #18
stevebd1 said:
The kinetic energy would convert into pressure (sometimes, pressure is described as confined KE) and Einstein's algebraic equation for gravity is [itex]g=\rho+3P[/itex] where [itex]\rho[/itex] is density and P is pressure and so the gravity would increase, pulling the star in on itself.
Fine, confined KE will contribute to gravity by tiny bit so that expansion will be reduced by tiny bit but summary effect will be expansion not contraction.
 
  • #19
zonde said:
Fine, confined KE will contribute to gravity by tiny bit so that expansion will be reduced by tiny bit but summary effect will be expansion not contraction.

Can you provide equations or proof that demonstrates this. The common census is that as a neutron star increases in mass, it's radius reduces.
 
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  • #20
zonde said:
Fine, confined KE will contribute to gravity by tiny bit so that expansion will be reduced by tiny bit but summary effect will be expansion not contraction.

I'm having a discussion with zonde about a similar point in another thread; I posted this earlier today:

https://www.physicsforums.com/showpost.php?p=3497951&postcount=26

in which I reminded myself and zonde that a self-gravitating body has a negative heat capacity. That means that if you add energy to it, it expands and cools (i.e., its temperature goes *down*, not up), and if you take energy away from it, it contracts and heats up (i.e., its temperature goes *up*, not down). In other words, increasing the temperature of such a body does *not* create a tendency to expand against gravity.

Similar reasoning applies to the case under discussion here; the only difference is that, for an object above the maximum possible mass for a neutron star (the TOV limit), it will collapse even if it is not radiating away any energy to the outside universe. But that doesn't change the fact that the increasing temperature as it contracts does *not* compensate for the increased gravity that is pulling it in.
 
  • #21
zonde said:
Gravitation potential becomes lower as we go toward center of mass. Because of that event horizon should first form at the center of gravitating body that is going to turn into the black hole and then move outward. I believe that is the way how birth of BH is modeled.

This is correct as long as by "horizon" you mean "absolute horizon", i.e., the boundary of the region from which light signals cannot escape to infinity. However, this is *not* the same as an "apparent horizon", which is a "trapped surface" at which outgoing light signals no longer move outward. The distinction is important; see next comment.

zonde said:
But at the center of gravitating body mass is not falling anywhere. So it should be extremely time dilated right before it turns into the black hole. So from where this "seed" black hole appears at the center of the body?

When the absolute horizon first forms at the center of the gravitating body, there is no apparent horizon; outgoing light rays are still moving outward. That also means that there is no extreme time dilation, since the extreme time dilation near a black hole horizon is due to the presence of an apparent horizon (trapped surface) there, where outgoing light rays don't move outward. At the time when the absolute horizon forms, the time dilation at the center of the star (r = 0) doesn't change discontinuously at all. As the star collapses and the density at r = 0 increases, the "time dilation" there will gradually increase as well, but even that statement is subject to qualifications; see the end of this post.

Here's the way I picture the absolute horizon. Suppose that time t = 0, in the exterior Schwarzschild time coordinate that applies outside of the collapsing body, is the time at which the surface of the body is just passing inward through the Schwarzschild radius r = 2M. That is the time at which the apparent horizon forms, and the extreme time dilation occurs. Now consider a light ray emitted outward from r = 0 at some time prior to t = 0, such that that outgoing light ray just reaches r = 2M at t = 0. That light ray will then remain at r = 2M for all times greater than t = 0, since there is now a trapped surface there and outgoing light rays can no longer move outward. In fact, that light ray lies on the absolute horizon. But when the light ray first starts out at r = 0, it is moving outward, and observers inside the star who see it moving outward would not notice any unusual time dilation. The fact that that light ray will actually never get beyond r = 2M depends on the global structure of the entire spacetime; it's not something you can observe locally.

Regarding time dilation, it's also important to remember that time dilation is relative. An observer hovering near a black hole horizon doesn't notice any unusual time dilation locally; only by comparing his clock with that of someone far away (for example, by exchanging light signals) can he tell that much more time has passed in the faraway universe than has elapsed by his local clock.

Similarly, locally, observers inside the star after the absolute horizon has formed and has passed outward beyond their radius still would not notice anything unusual. Only by trying and failing to send light signals outward beyond the absolute horizon could they in principle tell that they were behind it. Eventually, of course, they would end up at the singularity at r = 0; either when the collapsing star passed inward through their radius and carried them with it, or, if they were able to escape the star's surface as it collapsed, eventually they would still hit the singularity since they are inside the horizon.
 
  • #22
stevebd1 said:
Can you provide equations or proof that demonstrates this. The common census is that as a neutron star increases in mass, it's radius reduces.
Do you agree that classical physics and in particular http://en.wikipedia.org/wiki/Virial_theorem" [Broken] (thanks to PeterDonis for pointing that out) says that gravitating body has to expand as you add energy to the body?

It says that for gravitating body Upot=-2Ukin. As a result adding more energy to the body increases it' s average potential energy (body expands) and decreases kinetic energy (it cools down on average).
[tex]U_{tot}+\Delta U=(U_{pot}+2\Delta U)+(U_{kin}-\Delta U)[/tex]

If you agree with that then your statement becomes rather non trivial and I think that the burden of proof is entirely on you. It could mean that corrections to classical result under certain conditions would have to grow so large (in right direction) that they actually invert classical result.
 
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  • #23
PeterDonis said:
This is correct as long as by "horizon" you mean "absolute horizon", i.e., the boundary of the region from which light signals cannot escape to infinity. However, this is *not* the same as an "apparent horizon", which is a "trapped surface" at which outgoing light signals no longer move outward. The distinction is important; see next comment.

When the absolute horizon first forms at the center of the gravitating body, there is no apparent horizon; outgoing light rays are still moving outward. That also means that there is no extreme time dilation, since the extreme time dilation near a black hole horizon is due to the presence of an apparent horizon (trapped surface) there, where outgoing light rays don't move outward. At the time when the absolute horizon forms, the time dilation at the center of the star (r = 0) doesn't change discontinuously at all. As the star collapses and the density at r = 0 increases, the "time dilation" there will gradually increase as well, but even that statement is subject to qualifications; see the end of this post.

Here's the way I picture the absolute horizon. Suppose that time t = 0, in the exterior Schwarzschild time coordinate that applies outside of the collapsing body, is the time at which the surface of the body is just passing inward through the Schwarzschild radius r = 2M. That is the time at which the apparent horizon forms, and the extreme time dilation occurs. Now consider a light ray emitted outward from r = 0 at some time prior to t = 0, such that that outgoing light ray just reaches r = 2M at t = 0. That light ray will then remain at r = 2M for all times greater than t = 0, since there is now a trapped surface there and outgoing light rays can no longer move outward. In fact, that light ray lies on the absolute horizon. But when the light ray first starts out at r = 0, it is moving outward, and observers inside the star who see it moving outward would not notice any unusual time dilation. The fact that that light ray will actually never get beyond r = 2M depends on the global structure of the entire spacetime; it's not something you can observe locally.
I am not sure I understood the difference between apparent and absolute horizon. In one case light that is going outwards can't reach infinity in other case light that is going outwards is not going outwards (obviously it can't reach infinity just the same).

PeterDonis said:
Regarding time dilation, it's also important to remember that time dilation is relative. An observer hovering near a black hole horizon doesn't notice any unusual time dilation locally; only by comparing his clock with that of someone far away (for example, by exchanging light signals) can he tell that much more time has passed in the faraway universe than has elapsed by his local clock.
Yes of course time dilation is relative. But to find out what is time dilation at the center of gravitating body (let' s imagine that) we can observe light that is coming from the rest of the universe. From it' s blueshift we can determine our time dilation. So if we speak about time dilation at the center of gravitating body that is going to become black hole we can speak about blueshift of incoming radiation. So let me restate the question - would there be extreme blueshift of incoming radiation?
 
  • #24
zonde said:
I am not sure I understood the difference between apparent and absolute horizon. In one case light that is going outwards can't reach infinity in other case light that is going outwards is not going outwards (obviously it can't reach infinity just the same).

The apparent horizon is a local phenomenon; you just look at outgoing light beams in a small local region of spacetime and see if they are moving outward (increasing in radius).

The absolute horizon is global; you have to know the entire future path of light beams to know where the absolute horizon is. For example, you could be inside the absolute horizon and still not see an apparent horizon (as with the observers inside the star in my example, after the absolute horizon has passed them as it expands outward, before the star has collapsed inside r = 2M). That is, you could see outgoing light beams moving outward in your vicinity, but not be able to tell, at that time, that further in the future, those light beams will stop moving outward and be trapped when an apparent horizon forms in the future.

zonde said:
Yes of course time dilation is relative. But to find out what is time dilation at the center of gravitating body (let' s imagine that) we can observe light that is coming from the rest of the universe. From it' s blueshift we can determine our time dilation. So if we speak about time dilation at the center of gravitating body that is going to become black hole we can speak about blueshift of incoming radiation. So let me restate the question - would there be extreme blueshift of incoming radiation?

At the instant when the absolute horizon forms at r = 0 and begins expanding outward, no, the blueshift would not be "extreme"; more precisely, it would be the same at that point as it was before in the center of the star. As the star collapses, the blueshift at r = 0 becomes greater because the density at r = 0 increases, but the change is continuous and does not show any different behavior at the instant when the absolute horizon forms.
 
  • #25
zonde said:
Do you agree that classical physics and in particular http://en.wikipedia.org/wiki/Virial_theorem" [Broken] (thanks to PeterDonis for pointing that out) says that gravitating body has to expand as you add energy to the body?

It says that for gravitating body Upot=-2Ukin. As a result adding more energy to the body increases it' s average potential energy (body expands) and decreases kinetic energy (it cools down on average).
[tex]U_{tot}+\Delta U=(U_{pot}+2\Delta U)+(U_{kin}-\Delta U)[/tex]

As I noted in the other thread we're having on gravitational collapse, this form of the virial theorem is limited, as I understand it, to the case of zero pressure, where all bodies are moving on geodesics (i.e., solely under the influence of gravity). I believe it gets more complicated when pressure is included, though I believe the general conclusion, that bodies in hydrostatic equilibrium expand (and cool) when you add energy and contract (and warm up) when you take away energy, still holds. However, see next comment.

zonde said:
If you agree with that then your statement becomes rather non trivial and I think that the burden of proof is entirely on you. It could mean that corrections to classical result under certain conditions would have to grow so large (in right direction) that they actually invert classical result.

All of the logic above about what happens to a gravitating body when it gains or loses energy only applies if the body is in a stable equilibrium, or more precisely if it is gaining or losing mass (energy) slowly enough that it can make a quasi-stable transition between stable equilibrium configurations. But the whole point of the TOV limit for neutron stars (or the Chandrasekhar limit for white dwarfs) is that for a body with total mass (energy) above the limit there is *no* stable equilibrium! (The reason is that the central pressure would have to be infinite for a stable equilibrium to exist.) What stevebd1 has been saying about pressure increasing total gravitational pull is an explanation of *why* there is no stable equilibrium; it's because as the body increases its pressure to hold itself up against gravity, that increase in pressure itself increases the gravity it has to hold itself up against. This then requires more pressure to hold the body up, which increases the total gravity further, etc...until you reach the limit beyond which even an infinite pressure can't hold the body up.
 
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  • #26
zonde said:
If you agree with that then your statement becomes rather non trivial and I think that the burden of proof is entirely on you. It could mean that corrections to classical result under certain conditions would have to grow so large (in right direction) that they actually invert classical result.


Not hard evidence but here's an extract from the 'curious about astronomy' website, http://curious.astro.cornell.edu/question.php?number=263" [Broken]
..for objects less massive than Jupiter, adding mass increases their size. For objects more massive than Jupiter, adding even more mass decreases their size due to increased gravity and pressure. Since WDs and NSs are much more massive than Jupiter, their sizes decrease with increasing mass.

The link provides a bit more information.


On more mathmatical level, Fig. 3 on page 5 of this paper, http://arxiv.org/PS_cache/arxiv/pdf/0705/0705.2708v2.pdf" [Broken] shows the radius of neutron stars reducing as the mass increases.


It appears that it is generally accepted that neutron stars reduce in size as they grow in mass.
 
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  • #27
..for objects less massive than Jupiter, adding mass increases their size. For objects more massive than Jupiter, adding even more mass decreases their size due to increased gravity and pressure. Since WDs and NSs are much more massive than Jupiter, their sizes decrease with increasing mass.

This link reminded me that the heat capacity issue is more complex than I had implied in my previous posts. The basic argument that I gave in previous posts for a self-gravitating body having a negative heat capacity depends, as I understand it, on the body having either zero pressure (the simple case where the virial theorem works as zonde's post indicated), or being in hydrostatic equilibrium with a non-zero pressure that is kinetic, i.e., it increases as temperature increases.

Let me give another short quote from the same web page, since the one stevebd1 gave, from later in the article, actually misstates things a bit (or else the article writer was pressed for time):

So let's consider a small giant planet, like Neptune. That planet is supported entirely by gas and degeneracy pressure. If we were to slowly add mass to Neptune, the planet would begin to grow in radius. The gravity and pressure would increase as well, of course, but not enough to offset the increase in volume. This will keep occurring until our planet is a few tens or hundreds the size of Jupiter.

As you can see, the actual "cutoff", where the change in radius on adding mass becomes negative instead of positive, is "a few tens or hundreds the size of Jupiter". That's about a tenth of the mass of the Sun. I believe the reason for the change in sign at around that size is that, up until then, degeneracy pressure is small compared to kinetic pressure (what the quote calls "gas pressure"). As degeneracy pressure gets larger and larger, the dependence of the total pressure on temperature gets weaker and weaker; or, put another way, the fraction of the total pressure that contributes to gravity (since all pressure does) but does *not* contribute to the expansion of the body (because it's not kinetic) gets larger and larger. I believe this is what causes the body, past a certain point, to get smaller instead of larger as it continues to gain mass (energy).

How does this affect heat capacity? I believe (but I haven't confirmed by calculation) that once a body is in the regime where degeneracy pressure is dominant, and it gets smaller when mass is added, its heat capacity becomes positive again. This is because, if adding energy causes the body to contract, the material in the body is basically falling a bit in its own gravitational field, which should cause it to gain kinetic energy and heat up. So I think it *is* possible for a white dwarf or neutron star to exist in stable thermal equilibrium with the outside universe, provided it is below the appropriate mass limit. Above the mass limit, as I said before, there is no possible stable equilibrium configuration, and the object must collapse.
 
  • #28
stevebd1 said:
Not hard evidence but here's an extract from the 'curious about astronomy' website, http://curious.astro.cornell.edu/question.php?number=263" [Broken]

..for objects less massive than Jupiter, adding mass increases their size. For objects more massive than Jupiter, adding even more mass decreases their size due to increased gravity and pressure. Since WDs and NSs are much more massive than Jupiter, their sizes decrease with increasing mass.
Let's look at this reasoning for hidden assumptions.
What does it means to add mass? You can't simply import mass at the surface of the body.
So if we want more physical example we can take example where we move mass from more distant place toward body until it reaches surface. Now let's consider joined system of this further away matter and the body. In order to lower gravitational potential energy of this additional mass total system has to lower it's total energy i.e. it has to get rid of the energy.

So it turns out that hidden assumption in this reasoning from the article is that the body actually can emit heat.

If you do not make that assumption then another possible scenario for matter falling on surface of the body is conversion of additional kinetic energy along with part of body's own kinetic energy into potential energy and consequent expanding and cooling of the body. And at extreme case body can simply fall apart forming cloud of debris.

stevebd1 said:
It appears that it is generally accepted that neutron stars reduce in size as they grow in mass.
I don't question that. But consensus viewpoint is not a proof of an argument.
For example this relationship can be valid but interpretation of physical mechanism behind this relationship can be incorrect.
 
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  • #29
Here is the paper that was the source for mass/radius chart (fig. 3) from the paper mentioned in post 26-

'Strange Quark Matter and Compact Stars' by Fridolin Weber
http://arxiv.org/abs/astro-ph/0407155

The chart is on page 29, Fig. 15. This paper appears to have more information/equations and also compares the various models to actual observed neutron stars.
 
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  • #30
zonde said:
In order to lower gravitational potential energy of this additional mass total system has to lower it's total energy i.e. it has to get rid of the energy.

Not if the mass just falls from far away until it hits the body. Total energy is constant in that scenario; the body's gravitational potential energy when it's far away becomes kinetic energy when it hits the gravitating body. Assume (which is an idealization, yes) that none of the falling mass gets thrown back upward by the impact, it all becomes part of the gravitating body, along with all the kinetic energy it's carrying (which all becomes internal heat energy in the new, more massive gravitating body). That means the new combined body (original gravitating body, plus falling mass, plus all the kinetic energy gained by the mass as it fell) must reach a new static equilibrium configuration with a higher total energy than before. And if the original gravitating body was more massive than the threshold given earlier (ten to a hundred times the mass of Jupiter), the new static equilibrium configuration I just described will have a *smaller* radius than the old one did.

zonde said:
If you do not make that assumption then another possible scenario for matter falling on surface of the body is conversion of additional kinetic energy along with part of body's own kinetic energy into potential energy and consequent expanding and cooling of the body. And at extreme case body can simply fall apart forming cloud of debris.

If the body falls apart, it does not reach a new static equilibrium configuration. Such a case is not covered by the quotes stevebd1 gave. Those articles are only discussing stable, static equilibrium configurations. Obviously there is no guarantee, physically, that the system will end up in a static equilibrium after every possible change, but restricting discussion to static equilibrium seems reasonable in this thread given the question asked in the OP.

The other possibility you raise cannot result in a new static equilibrium; that is the point of the quotes stevebd1 gave. If the body were to start expanding and cooling as you say, due to some type of perturbation during the impact of the infalling mass, gravity would pull it back, and it would oscillate in radius until it settled down to a new static equilibrium, which, if the total energy was larger than before, would be *smaller* in radius than before.
 
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  • #31
stevebd1 said:
Here is the paper that was the source for mass/radius chart (fig. 3) from the paper mentioned in post 26-

'Strange Quark Matter and Compact Stars' by Fridolin Weber
http://arxiv.org/abs/astro-ph/0407155

The chart is on page 29, Fig. 15. This paper appears to have more information/equations and also compares the various models to actual observed neutron stars.
This paper is more about what a neutron star might like once it has formed with given mass and radius.
But our discussion stared with the question about the process how it can get there.

Your point was that neutron star reduces in radius as it acquires matter because pressure contributes to gravity.

My point is that neutron star reduces in radius if (because) it radiates away "pressure" energy.

I don't see how the paper you gave can contribute to our discussion.
 
  • #32
PeterDonis said:
Not if the mass just falls from far away until it hits the body. Total energy is constant in that scenario; the body's gravitational potential energy when it's far away becomes kinetic energy when it hits the gravitating body. Assume (which is an idealization, yes) that none of the falling mass gets thrown back upward by the impact, it all becomes part of the gravitating body, along with all the kinetic energy it's carrying (which all becomes internal heat energy in the new, more massive gravitating body). That means the new combined body (original gravitating body, plus falling mass, plus all the kinetic energy gained by the mass as it fell) must reach a new static equilibrium configuration with a higher total energy than before. And if the original gravitating body was more massive than the threshold given earlier (ten to a hundred times the mass of Jupiter), the new static equilibrium configuration I just described will have a *smaller* radius than the old one did.



If the body falls apart, it does not reach a new static equilibrium configuration. Such a case is not covered by the quotes stevebd1 gave. Those articles are only discussing stable, static equilibrium configurations. Obviously there is no guarantee, physically, that the system will end up in a static equilibrium after every possible change, but restricting discussion to static equilibrium seems reasonable in this thread given the question asked in the OP.

The other possibility you raise cannot result in a new static equilibrium; that is the point of the quotes stevebd1 gave. If the body were to start expanding and cooling as you say, due to some type of perturbation during the impact of the infalling mass, gravity would pull it back, and it would oscillate in radius until it settled down to a new static equilibrium, which, if the total energy was larger than before, would be *smaller* in radius than before.
I can not agree with underlined statement. This is exactly opposite to conclusions that follow from virial theorem.
Please provide arguments.
 
  • #33
zonde said:
I can not agree with underlined statement. This is exactly opposite to conclusions that follow from virial theorem.
Please provide arguments.

As I said before, the virial theorem does not apply to a fluid in hydrostatic equilibrium with a non-zero pressure.

Also, as far as arguments go, your intuition that a body should expand when it gains energy depends on the body's pressure being kinetic (i.e., dependent on temperature). As I noted in a previous post, as degeneracy pressure becomes a larger and larger fraction of total pressure, the dependence of pressure on temperature gets weaker and weaker. Once degeneracy pressure is high enough, the increase in gravity caused by an increase in total energy (including the extra gravity caused by the increased pressure) compresses the body more than the increase in pressure and temperature expands it, so on net it contracts when it gains energy.
 
  • #34
Passionflower said:
Whether something is a black hole not has nothing to do with the mass. The mass of a grain of salt could be a black hole as well.

Actually the amount of matter is not relevant, it is the ratio between area and mass that matters.

A non-spinning object becomes (or is already) a black hole if the ratio between the area it occupies and the area that represents its mass is smaller than 4. As soon as this happens the object's occupied area will shrink to zero.

E.g.:

[tex]
{A_{occupied} \over A_{mass} } < 4
[/tex]

Should there be an allowance for coulomb repulsion, or is that assumed in that inequality?
 
  • #35
An extract from Wikipedia's entry for http://en.wikipedia.org/wiki/Degenerate_matter#Concept"-
Unlike a classical ideal gas, whose pressure is proportional to its temperature (P=nkT/V, where P is pressure, V is the volume, n is the number of particles—typically atoms or molecules—k is Boltzmann's constant, and T is temperature), the pressure exerted by degenerate matter depends only weakly on its temperature. In particular, the pressure remains nonzero even at absolute zero temperature. At relatively low densities*, the pressure of a fully degenerate gas is given by P=K(n/V)5/3, where K depends on the properties of the particles making up the gas. At very high densities, where most of the particles are forced into quantum states with relativistic energies, the pressure is given by P=K'(n/V)4/3, where K' again depends on the properties of the particles making up the gas.

Some idea of what K and K' represent are shown on page 16 of this paper where a slightly different interpretation of P has been used [itex](P=K\rho_0^\Gamma[/itex] where [itex]\small\Gamma[/itex] represents either 5/3 or 4/3)-

'Neutron Stars' by Kostas Kokkotas
http://www.tat.physik.uni-tuebingen.de/~kokkotas/Teaching/NS.BH.GW_files/GTR_course4.pdf

*'relatively low densities' are considered to be <<6e+018 kg/m3 for neutron stars.
 
Last edited by a moderator:
<h2>1. What is black hole matter accumulation?</h2><p>Black hole matter accumulation refers to the process by which matter, such as gas and dust, is pulled into a black hole due to its immense gravitational pull. As the matter gets closer to the black hole, it speeds up and heats up, emitting radiation before eventually crossing the event horizon and being trapped inside.</p><h2>2. How does matter accumulate in a black hole?</h2><p>Matter can accumulate in a black hole through a variety of ways, such as being pulled in by the black hole's gravity, being captured by the black hole's accretion disk, or being drawn in by the gravitational pull of a companion star.</p><h2>3. How does black hole matter accumulation affect the surrounding environment?</h2><p>The accumulation of matter in a black hole can have a significant impact on its surrounding environment. As the matter is pulled towards the black hole, it heats up and emits high levels of radiation, which can affect nearby objects and alter the dynamics of the surrounding space.</p><h2>4. Can black hole matter accumulation ever stop?</h2><p>Yes, black hole matter accumulation can stop if the black hole stops growing in size. This can happen when the black hole runs out of nearby matter to consume, or when it reaches a maximum size and can no longer pull in more matter.</p><h2>5. What can we learn from studying black hole matter accumulation?</h2><p>Studying black hole matter accumulation can provide valuable insights into the behavior of matter in extreme environments and can help us better understand the properties of black holes, which are some of the most mysterious objects in the universe. It can also help us test and refine our understanding of gravity and the laws of physics.</p>

1. What is black hole matter accumulation?

Black hole matter accumulation refers to the process by which matter, such as gas and dust, is pulled into a black hole due to its immense gravitational pull. As the matter gets closer to the black hole, it speeds up and heats up, emitting radiation before eventually crossing the event horizon and being trapped inside.

2. How does matter accumulate in a black hole?

Matter can accumulate in a black hole through a variety of ways, such as being pulled in by the black hole's gravity, being captured by the black hole's accretion disk, or being drawn in by the gravitational pull of a companion star.

3. How does black hole matter accumulation affect the surrounding environment?

The accumulation of matter in a black hole can have a significant impact on its surrounding environment. As the matter is pulled towards the black hole, it heats up and emits high levels of radiation, which can affect nearby objects and alter the dynamics of the surrounding space.

4. Can black hole matter accumulation ever stop?

Yes, black hole matter accumulation can stop if the black hole stops growing in size. This can happen when the black hole runs out of nearby matter to consume, or when it reaches a maximum size and can no longer pull in more matter.

5. What can we learn from studying black hole matter accumulation?

Studying black hole matter accumulation can provide valuable insights into the behavior of matter in extreme environments and can help us better understand the properties of black holes, which are some of the most mysterious objects in the universe. It can also help us test and refine our understanding of gravity and the laws of physics.

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