B Gravitational potential energy, a thought experiment

  • #51
PeterDonis said:
Is zero at infinity.
Ah I meant to say is greatest at infinity (or the farther the freefall starts).
Why would it be zero at infinity, or the greater the distance? (to avoid the singularities of infinity in general)
 
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  • #52
PeterDonis said:
Which is irrelevant to the OP's scenario. The total mass of the system in that case would be less than ##m + M##.And at an altitude just above the horizon of Sag A. That is the case under discussion in this thread.None of this is relevant unless some of the energy produced escapes to infinity, i.e., outside the box the OP specified (most likely as radiation, less likely as actual mass ejected). I explicitly ruled out this possibility in my post. Of course in real scenarios these things will happen, but I think discussion of them is premature until the OP understands the simpler idealized case that is under discussion.
The initial conditions had a mass of m+M, then the Sun gets accelerated and attains enough energy to rival it's own mass. How much does the box weigh?
There are more solutions to this. Either the initial mass is not m+M and GPE has actual mass.
Or KE ads no mass even though it can and should.
Or the mass of the box changes in time.
Or some other solution.
 
  • #53
Lok said:
It should'nt be unrelated, as anything that gives 24% more mass from a single interaction of a small part of this galaxy is not nothing.
Be aware, this should be 24% less mass, not more.

The process is this: the sun starts out far away. As it falls it gains KE and loses PE. When it is in the low PE high KE state the mass of the system is unchanged. The sun can collide with other objects, breaking apart, and thermalizing its KE. When it is in the low PE high thermal energy state the mass is still unchanged. The resulting hot mass can radiate energy away. Only after the radiation has left the box is the mass decreased. At that point it is a low PE and low thermal energy state. Only then is the mass lower.

There is a limit to how much the mass can drop, but if I recall correctly 24% is definitely possible.
 
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  • #54
Lok said:
I meant to say is greatest at infinity (or the farther the freefall starts).
Yes.

Lok said:
Why would it be zero at infinity, or the greater the distance?
You could define the value at infinity to be anything you like; if you define it to be anything except zero, you will just be adding an irrelevant constant that drops out of the analysis (because that constant cannot appear in the actual externally measured mass of the system, which is an observable and can't depend on what conventions you adopt). So it's easiest to just define the value at infinity to be zero.
 
  • #55
Lok said:
The initial conditions had a mass of m+M, then the Sun gets accelerated and attains enough energy to rival it's own mass. How much does the box weigh?
There are more solutions to this.
Not as you've stated the problem, no, because you have stated that the box is isolated. As has already been pointed out, if the box remains isolated the whole time (nothing goes in or out), then its externally measured mass cannot change. That is the only valid solution.
 
  • #56
PeroK said:
Are you sure this applies in GR?
I don’t see that this is a GR question. It’s basically about energy conservation and how we choose the zero point of total energy.
SR was dragged in only because OP has to convert energy to mass before they can add it to ##m+M## to work with the total mass/energy of the system. But because ##m## and ##M## are both constant there’s no need to do that; they could just be working with the sum of the potential and kinetic energy. Comparing ##m+M+E_K+E_P## when one or the other energy terms is zero doesn’t show us anything we won’t see just by looking at ##E_K+E_P##.

[edit to add - I posted this before it was fully baked, then finished it, which is what the exchange with @Vanadium 50 below was about]
 
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  • #57
Nugatory said:
I don’t see that this is a GR question.
It's not even an SR question.
 
  • #58
Vanadium 50 said:
It's not even an SR question.
Quite right…. Your post crossed my edit intended to complete my thought.
 
  • #59
PeroK said:
Are you sure this applies in GR? In terms of conservation of invariant mass?
In this particular case, yes. We have an isolated system, and its externally measured mass is constant.

PeroK said:
I thought that more generally we have conservation of stress-energy.
We have local conservation of stress-energy in GR, but that does not come into play here as we are talking about the externally measured mass of an isolated system. That is a global quantity.

PeroK said:
There is additional stress-energy - although even that is not so clear cut, as the gravitational field is not part of the stress-energy tensor, but described separately.
Which means there is no additional stress-energy. The various "gravitational pseudo-tensors" in the literature are not stress-energy. And in this case they don't tell us anything useful that we can't get from the much simpler analysis that has already been done in this thread.
 
  • #60
Lok said:
it's own mass. How much does the box weigh?
I suggest the following:

Clear up the concepts:
##m## - mass of the Sun
##M## - mass Sag. A
##(t,r,\theta,\phi)## -spherical coordinates centered at Sag. The coordinates ##\theta## and ##\phi## are constant for the Sun.

Weight is the force that occurs when you place a mass in a gravitational field.
You shouldn't use it because then you would need a third object in whose gravitational field these two (the Sun and Sagittarius A) would be.

Potential energy, kinetic energy and work are three terms that are closely related.

For potential energy, you should choose one of two conventions.
One is that the potential energy is maximal at the beginning and decreases towards zero, and the other is that it is zero at the beginning and becomes more and more negative.

As the Sun falls towards Sag and it does some work (##W_{ork}=F_{orce}\cdot d_{istance}##), its potential energy decreases and its kinetic energy increases.

Try to analyze what is happening using:

1. Classical Newtonian mechanics when velocities are small compared to the speed of light and when space-time is approximately flat

2. Special relativity when the speed of the Sun is not negligible compared to the speed of light, but the Sun is not close to Sag A (space-time of significant curvature).
The rest masses of both objects will remain the same, but you should pay attention to the relativistic mass of the Sun.
Relativistic mass is not "real" mass, but only the body's resistance to acceleration (in this case, the gravitational force of Sag A)
The sun will accelerate less and react more sluggishly to the external force than in the case of lower speeds of Newtonian mechanics.

3. General relativity.
##r_s=\frac{2GM}{c^2}## the Schwarzschild radius (the event horizon) of Sag A
Because the coordinates ##\theta## and ##\phi## are constant for the Sun you can simplify the Schwarzschild metric:
$$ds^2=-(1-\frac{r_s}{r})c^2dt^2+\frac{dr^2}{1-\frac{r_s}{r}}+\cancel{r^2(d\theta^2+\sin^2 \theta d\phi^2)}$$
 
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  • #61
Bosko said:
Weight is the force that occurs when you place a mass in a gravitational field.
You shouldn't use it because then you would need a third object in whose gravitational field these two (the Sun and Sagittarius A) would be.
This is a valid point; I think everyone commenting in the thread has assumed that the OP actually meant "invariant mass of the system" instead of "weight", but it is good to be precise.

Bosko said:
Classical Newtonian mechanics when velocities are small compared to the speed of light and when space-time is approximately flat
This obviously won't apply at the end state of the scenario, where neither of these things are true.

Bosko said:
Special relativity when the speed of the Sun is not negligible compared to the speed of light, but the Sun is not close to Sag A (space-time of significant curvature).
This won't tell us anything useful. In fact no dynamical analysis is required at all; the question can be answered purely in terms of energy conservation. As has already been done in the thread.

Bosko said:
Relativistic mass is not "real" mass, but only the body's resistance to acceleration (in this case, the gravitational force of Sag A)
This is wrong. "Acceleration" due to gravity is not proper acceleration; it is not felt as a force, and therefore relativistic mass as "inertia" (resistance to an applied force) does not apply.

Bosko said:
General relativity.
This is implied by the use of a black hole in the scenario, yes. However, in this particular case the analysis looks exactly the same as a Newtonian analysis using energy conservation.
 
  • #62
PeterDonis said:
This obviously won't apply at the end state of the scenario, where neither of these things are true.
Of course you are right but OP is talking about masses, but in fact he is interested in speed, kinetic energy stored as relativistic mass and the energy of the collision that will happen at the end.
I thought he should practice Newtonian mechanics and then move on to more complex relativistic formulas.
PeterDonis said:
This is wrong. "Acceleration" due to gravity is not proper acceleration; it is not felt as a force, and therefore relativistic mass as "inertia" (resistance to an applied force) does not apply.
It is also true, IMO, but you speak from the point of view of GR and I from a static observer in SR relative to Sag A
PeterDonis said:
This is implied by the use of a black hole in the scenario, yes. However, in this particular case the analysis looks exactly the same as a Newtonian analysis using energy conservation.
Of course, but reading the OP, it seems to me that he is still interested in final speed and kinetic energy.
 
  • #63
Bosko said:
kinetic energy stored as relativistic mass
Is, as I have already said, irrelevant to the scenario under discussion (and relativistic mass is an outdated concept anyway, as you will see if you search for relevant PF Insights articles and previous threads).

Bosko said:
the energy of the collision that will happen at the end
There is no collision. Sag A is a black hole; the Sun just falls through its horizon.

Bosko said:
I thought he should practice Newtonian mechanics and then move on to more complex relativistic formulas.
As I have already said, there is no need to dynamically analyze the situation at all. The analysis that is actually needed looks the same in Newtonian mechanics as it does in GR. You can't do the analysis in SR (see further comments below).

Bosko said:
a static observer in SR relative to Sag A
There is no such thing in this scenario since Sag A is a black hole and the spacetime around it is curved, and the Sun does not stay a very large distance away for the entire scenario so you cannot ignore the curvature of the spacetime.

Bosko said:
reading the OP, it seems to me that he is still interested in final speed and kinetic energy.
Only because he didn't understand when he posted the OP that the Sun's kinetic energy is exactly canceled by negative gravitational potential energy, so the externally measured mass of the system is constant even though the Sun's kinetic energy changes during the scenario.
 
  • #64
Ibix said:
The energy in your case is already in the system and already accounted for in the mass measurement. So the mass does not increase.

Again, look up Oppenheimer-Snyder collapse for an analytically tractable case.
Nifty little paper with nice heart warming historical notations.
I see where the similarity begins, but they do not treat mass and potential gravitational energy at all and are more concerned with the physicality of the geometry as far as i understood it.
 
  • #65
PeroK said:
Heat is internal energy that is effectively frame independent. That contributes to the rest mass or invariant mass of an object. And, that contributes to its gravitational mass.

The object's KE is entirely frame dependent. There is always a frame of reference in which the centre of mass of the object is at rest. You can't simply take that KE to be gravitating mass. That's why you need to be a lot more precise about "mass-energy equivalence". And, especially, once you go beyond SR into GR and cosmology.
There is an argument to be made that heat is randomly distributed KE vectors in a body.
 
  • #66
Bosko said:
Of course, but reading the OP, it seems to me that he is still interested in final speed and kinetic energy.
Not really interested in final speed and real value of KE as long as it is >0 and can in theory be counted as a gravitationally observable mass.
 
  • #67
PeterDonis said:
There is no collision. Sag A is a black hole; the Sun just falls through its horizon.
I used the Sun and Sag A* as the initial bodies to underline the massive amount of energy that such a system holds as potential energy. It could have been an electron and a star, were the collision can easily produce rest mass, but then I would get quantum arguments of fields holding whatever mass somewhere, I wanted to avoid this and make it cosmological because IMO the amount of mass that comes about is of dark matter proportions.
 
  • #68
PeterDonis said:
Only because he didn't understand when he posted the OP that the Sun's kinetic energy is exactly canceled by negative gravitational potential energy, so the externally measured mass of the system is constant even though the Sun's kinetic energy changes during the scenario.
I still do not understand this. In the OP I used the as in Wiki weirdly formulate value for Gravitational potential energy.
U=-GMm/R, where R is the smallest distance that can be attained by the masses, in my case the radius of Sag A* or close by, and that is the final state, it does not matter what happens after.
Thus I would not state that KE cancels out GPE, but rather one transforms into another.
So either the extra 24% mass is a real thing, and this leaves me wondering where it is distributed in the initial state.
Or it is a figment of equations and there should be no difference in outcome whether there is or there isn't KE in the final state.
 
  • #69
Nugatory said:
I don’t see that this is a GR question. It’s basically about energy conservation and how we choose the zero point of total energy.
SR was dragged in only because OP has to convert energy to mass before they can add it to ##m+M## to work with the total mass/energy of the system. But because ##m## and ##M## are both constant there’s no need to do that; they could just be working with the sum of the potential and kinetic energy. Comparing ##m+M+E_K+E_P## when one or the other energy terms is zero doesn’t show us anything we won’t see just by looking at ##E_K+E_P##.

[edit to add - I posted this before it was fully baked, then finished it, which is what the exchange with @Vanadium 50 below was about]
Still would those ##m+M+E_K+E_P## energy terms add to the mass of the box?
If yes, how is that mass distributed in the initial state as the final state is less of an issue.
 
  • #70
Bosko said:
Clear up the concepts:
##m## - mass of the Sun
##M## - mass Sag. A
##(t,r,\theta,\phi)## -spherical coordinates centered at Sag. The coordinates ##\theta## and ##\phi## are constant for the Sun.
I used the Sun Sag A* masses and radii as found on Wiki. But they do not matter as long as they are non zero, assuming initial state distance is greater than the final state.
Bosko said:
Relativistic mass is not "real" mass, but only the body's resistance to acceleration (in this case, the gravitational force of Sag A)
I agree up to a point as KE does have a measurable mass via e.g. heat (non uniform energy vectors) can produce rest mass via nuclear or pair production (thus I am a bit liberal with their use interchangeably) so having uniform KE in one specific direction does not seem to me to be different.
IMO the moving Sun should have more gravitationally measurable mass.

I am going for dark matter of course, as that 24% is only the contribution of GPE of the SMBH Sag A* and the total GPE should account for all masses and distances in the Milky way once the Sun ends up in the final state somewhere in the center.

As a side note I find it interesting to calculate this for more mundane celestial bodies.
So Moon Earth system ends up 6.9e-10% (basically a rounding error).
Earth Sun system ends up as 6.36e-10% (less of a basic rounding error).
So if true, this physically shows up only for some pretty extreme cases of BH or galaxies.
 
  • #71
Lok said:
they do not treat mass and potential gravitational energy at all and are more concerned with the physicality of the geometry as far as i understood it.
The mass parameter of the exterior geometry does not change, even though the FLRW region starts instantaneously static and collapses into a black hole. Thus the measured mass does not change even as the matter accelerates. This is an analytically tractable example of what we've been telling you.
 
  • #72
Ibix said:
The mass parameter of the exterior geometry does not change, even though the FLRW region starts instantaneously static and collapses into a black hole. Thus the measured mass does not change even as the matter accelerates. This is an analytically tractable example of what we've been telling you.
Yet they do not discuss KE and GPE while falling even though these are present in their simplified model, thus it is mostly a looking at the box form outside and seeing/assuming that as the mass does not change.
Their case is also simplified in as KE of some gas entering the BH has an opposite analogue on the other side of the BH, effectively canceling it and taking it out of the equations.
 
  • #73
Dale said:
Be aware, this should be 24% less mass, not more.

The process is this: the sun starts out far away. As it falls it gains KE and loses PE. When it is in the low PE high KE state the mass of the system is unchanged. The sun can collide with other objects, breaking apart, and thermalizing its KE. When it is in the low PE high thermal energy state the mass is still unchanged. The resulting hot mass can radiate energy away. Only after the radiation has left the box is the mass decreased. At that point it is a low PE and low thermal energy state. Only then is the mass lower.

There is a limit to how much the mass can drop, but if I recall correctly 24% is definitely possible.
More in comparison to m+M of initial state, as in the astronomically visually observable mass of the 2 body system at rest. Not the gravitationally lensed mass, as my assumption is that includes the 24% extra mass somewhere somehow. Therefore my conundrum.
I am liberal in my assumption KE has mass, as that mass can be created via thermalizing, and I assume it is not created instantaneously at thermalisation as that would violate conservation of mass, a law I try to keep in this case.
 
  • #74
PeterDonis said:
Not as you've stated the problem, no, because you have stated that the box is isolated. As has already been pointed out, if the box remains isolated the whole time (nothing goes in or out), then its externally measured mass cannot change. That is the only valid solution.
I totally agree via conservation of mass kind of reasoning. But if the Sun can attain a higher mass by transforming GPE into KE which can be transformed into rest mass, where was that mass in the initial state?
 
  • #75
Ibix said:
The mass parameter of the exterior geometry does not change, even though the FLRW region starts instantaneously static and collapses into a black hole. Thus the measured mass does not change even as the matter accelerates. This is an analytically tractable example of what we've been telling you.
How can the initial geometry be described by a single mass parameter? In the vicinity of the black hole, we will have approximately a Schwarzschild geometry with mass ##M##; and, in the vicinity of the star, we will have an approximately Schwarzschild geometry with mass ##m##. I would expect the geometry to have two mass parameters. Why wouldn't it?

Asymptotically, I would expect there to be a single parameter of approximately ##M + m##. I don't understand whether this is precisely ##M + m## or somehow includes the GPE of the two-body system? This is what I thought the Landau-Lifschitz pseudotensor was doing. Then it would be ##M + m + \Delta##.

In any case, after the collision, I expect we have a single Schwarzschild geometry with mass ##M + m + \Delta##. For this reason, I wasn't expecting conservation of mass to make sense in the full GR solution - unless we invoke the L-L pseudotensor. I also wasn't expecting "invariant mass" to make sense in a global GR scenario like this.

Finally, I don't understand how we can invoke the Newtonian GPE in a scenario where one body attains relativistic speeds.
 
  • #76
Nugatory said:
I don’t see that this is a GR question.
This response baffles me. See my questions above.
 
  • #77
PeroK said:
Finally, I don't understand how we can invoke the Newtonian GPE in a scenario where one body attains relativistic speeds.
I would not bother that much with relativistic effects as even if the speed is small and said effects are negligeble, there should be GPE to KE mass in the system that adds to the m+M.
I went close to Sag A* in my OP only to show the magnitude of the effect in comparison to a know intuitive quantity of mass like our Sun.
 
  • #78
Lok said:
I would not bother that much with relativistic effects as even if the speed is small and said effects are negligeble, there should be GPE to KE mass in the system that adds to the m+M.
You can't mix Newtonian mechanics with ##E = mc^2##, which is a fundamentally relativistic concept.
 
  • #79
PeroK said:
You can't mix Newtonian mechanics with ##E = mc^2##, which is a fundamentally relativistic concept.
You can calculate the KE via relativistic effects if you wish, would it be much different? As long as it is non-zero, it is a problem.
 
  • #80
Lok said:
You can calculate the KE via relativistic effects if you wish, would it be much different? As long as it is non-zero, it is a problem.
That approach makes no sense to me. How are you not going to get a contradiction somewhere?
 
  • #81
PeroK said:
That approach makes no sense to me. How are you not going to get a contradiction somewhere?
IMO this problem is a contradiction already. It either violates conservation of mass in the closed box or points to GPE as actual rest mass somehow.
As usual when a contradiction appears, eventually something new gets learned, even though the possibility of it not being new to anybody other than myself is forever present.
 
  • #82
Lok said:
conservation of mass
What do you mean by this ^^^^?
 
  • #83
Hill said:
What do you mean by this ^^^^?
Conservation of mass within the box.
As in the inital state has a mass of m+M observably, and m+M+KE in the final. I assume conservation of mass of the box, which leads to the requirement for the initial state to have an extra rest mass in the form of GPE, or the m+M to change somehow.
And if this is not valid then the box mass changes with time and it is not conserved.
 
  • #84
Lok said:
It either violates conservation of mass
Newtonian physics has conservation of mass.

In SR, we have conservation of invariant mass (for a closed system). But not conservation of rest mass.

In GR we have the local conservation of stress-energy. The extent to which this entails the global "conservation of mass" is not clear to me.
 
  • #85
PeroK said:
In SR, we have conservation of invariant mass (for a closed system). But not conservation of rest mass.
I only used Newtonian for the energy calculation, but honestly any value of KE is already problematic, so it does not matter.
I do not know what happens in SR with the mass of the Sun as it speeds up, but as I remember it is not going down to compensate for the extra KE. It usually looks like it incorporates it, which is problematic still.
GR is above me and I cannot state it has a solution to this, and thus here I am asking if someone has an idea if it does.

I strongly encourage anybody to do the most basic calculation and see how much GPE is in a as OP system or galactic if one has available data and modeling software. It is above my current setup.
 
  • #86
Lok said:
I only used Newtonian for the energy calculation, but honestly any value of KE is already problematic
We already know that mixing Newtonian gravity and SR is problematic. That's why GR was developed.
 
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  • #87
According to the MTW's Gravitation,
Asymptotic flatness [is] the key to the definability of M and S.
I understand that there is no defined meaning of mass of the system in question as an absolute value. But there
are the attractive possibilities of defining and measuring all three quantities [charge-energy-angular-momentum] in any space that is asymptotically flat. ... Surrounding a region where any dynamics, however complicated, is going on, whenever the geometry is asymptotically flat to some specified degree of precision, then to that degree of precision it makes sense to speak of the total energy-momentum 4-vector of the dynamic region, P, and its total intrinsic angular momentum, S. Parallel transport of either around any closed curve in the flat region brings it back to its starting point unchanged. Moreover, it makes no difference how enormous are the departures from flatness in the dynamic region (black holes, collapsing stars, intense gravitational waves, etc.); far away the curvature will be weak, and the 4-momentum and angular momentum will reveal themselves by their imprints on the spacetime geometry.
 
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  • #88
Lok said:
IMO the moving Sun should have more gravitationally measurable mass.
It does not.
One way of seeing this is to ask yourself “moving relative to what?”

Say the sun is moving past me but at rest relative to you (so you consider me to be flying rapidly past a stationary sun while I consider you and the sun to be moving while I am at rest). But we both have to agree on the sun’s gravitational effects - for example, the sun is compressed by its own gravity and we have to agree about the pressure at the core - and this is only possible if the gravity is the same. For an extreme example, consider that if the moving sun did have more gravitationally measurable mass we would have the ridiculous situation where if I’m moving fast enough relative to the sun it would collapse into a black hole for me but not you.
 
  • #89
Nugatory said:
It does not.
One way of seeing this is to ask yourself “moving relative to what?”

Say the sun is moving past me but at rest relative to you (so you consider me to be flying rapidly past a stationary sun while I consider you and the sun to be moving while I am at rest). But we both have to agree on the sun’s gravitational effects - for example, the sun is compressed by its own gravity and we have to agree about the pressure at the core - and this is only possible if the gravity is the same. For an extreme example, consider that if the moving sun did have more gravitationally measurable mass we would have the ridiculous situation where if I’m moving fast enough relative to the sun it would collapse into a black hole for me but not you.
Interesting.
Would we agree about the same time-frame in which said gravity acts in the Sun's reference frame?
 
  • #90
Lok said:
Interesting.
Would we agree about the same time-frame in which said gravity acts in the Sun's reference frame?
I have no idea what you’re trying to ask here, but I do know from the timestamps that you spent no more than fifteen minutes thinking before posting, and that’s not enough.
 
  • #91
Nugatory said:
I have no idea what you’re trying to ask here, but I do know from the timestamps that you spent no more than fifteen minutes thinking before posting, and that’s not enough.
True, sorry for the hasty reply.
I mean to say that in your reference you would measure a higher total gravity of the moving Sun but also a slower time for clocks in the moving reference frame. And for everyone to experience the same outcomes these 2 effects can cancel out, or should. IMO.

Conversely, if you see time being slower in a Sun moving past you, would you be able to calculate it's gravity from observing an object free falling into it? And if gravity is slower by virtue of relative motion, would the Sun have less gravity acting upon your reference frame?
I hope this made some sense.
 
  • #92
Lok said:
More in comparison to m+M of initial state, as in the astronomically visually observable mass of the 2 body system at rest
I don’t know how I can be more clear about this. It is less, not more. It starts at M+m and remains M+m until radiation leaves the box. When radiation leaves the box the mass becomes less than M+m. At no point is it ever more.

Lok said:
As in the inital state has a mass of m+M observably, and m+M+KE in the final.
This is false. At no point is the mass ever greater than m+M. After the radiation leaves the box it becomes m+M-E where E is the energy of the radiation that leaves.

Lok said:
I assume it is not created instantaneously
There is no delay. The mass is M+m the entire time until the radiation leaves at which point it is without delay M+m-E.
 
  • #93
Dale said:
I don’t know how I can be more clear about this. It is less, not more. It starts at M+m and remains M+m until radiation leaves the box. When radiation leaves the box the mass becomes less than M+m. At no point is it ever more.

This is false. At no point is the mass ever greater than m+M. After the radiation leaves the box it becomes m+M-E where E is the energy of the radiation that leaves.
I explicitly avoided radiation leakeage by stopping the problem right before the merger. And ask what the weight of the box is initially versus Sun close to A*.
My gripe is with the system in the final state having a mass of m+M+ a big chunk of Kinetic energy that does something.
And I do concur KE having mass is an assumption that is most evident at an impact, but that would mean mass is generated at impact, which makes just as little sense if trying to conserve the mass in the box.
 
  • #94
Lok said:
I explicitly avoided radiation leakeage by stopping the problem right before the merger.
Then there is never any change in mass. Not at any time. The only way for the mass in the box to change is for something to leave the box.

Lok said:
that would mean mass is generated at impact
Mass is never generated in this scenario. In other related scenarios, the box will only gain mass if something enters from outside and it will only lose mass if something exits from inside. No internal state change of any kind changes the mass.

I hope that is sufficiently clear to avoid misunderstanding.
 
  • #95
Dale said:
Then there is never any change in mass. Not at any time. The only way for the mass in the box to change is for something to leave the box.

Mass is never generated in this scenario. In other related scenarios, the box will only gain mass if something enters from outside and it will only lose mass if something exits from inside. No internal state change of any kind changes the mass.
I do understand the mass conservation problem, but this does not explain what happens to m, M and the 24% solar mass equivalent energy in the final state so that it would show up as a total mass of m+M of the initial.
 
  • #96
Lok said:
this does not explain what happens to m, M and the 24% solar mass equivalent energy in the final state so that it would show up as a total mass of m+M of the initial
Does this explain it for you? If not, please ask about the part of the explanation that is confusing:
Dale said:
The process is this: the sun starts out far away. As it falls it gains KE and loses PE. When it is in the low PE high KE state the mass of the system is unchanged. The sun can collide with other objects, breaking apart, and thermalizing its KE. When it is in the low PE high thermal energy state the mass is still unchanged.
 
  • #97
Dale said:
Does this explain it for you? If not, please ask about the part of the explanation that is confusing:
Dale's:
So box starts out as m and an unspecified hard wall plus gravity from another source, Sun starts to attain kinetic energy losing PE, thermalizes it by hitting the wall, and creates actual rest mass via heat, fusion and pair production. What is the mass of the final thermalized Sun?
 
  • #98
Lok said:
creates actual rest mass via heat, fusion and pair production
The mass does not change at any point. Heat, fusion, and pair production do not change the mass inside the box.

Lok said:
What is the mass of the final thermalized Sun?
To determine that you would have to draw a box around the sun and keep track of anything that enters or leaves that box. If nothing enters or leaves then the mass would remain m. But of course in that case there would be no way for the KE to thermalize.
 
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  • #99
Lok said:
I do understand the mass conservation problem, but this does not explain what happens to m, M and the 24% solar mass equivalent energy in the final state so that it would show up as a total mass of m+M of the initial.
It may be worth reading this:

https://en.wikipedia.org/wiki/Mass_in_general_relativity

I think it says what I was trying to say nearly a hundred posts ago!
 
  • #100
Lok said:
they do not treat mass and potential gravitational energy at all and are more concerned with the physicality of the geometry as far as i understood it.
That is correct. The scenario they are analyzing is different from the scenario you are asking about. Their paper, as I have already said, does not give any useful information about your scenario.
 
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