What is the stress-energy-momentum tensor and its role in general relativity?

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In summary, the stress-energy-momentum tensor plays a crucial role in GR and its existence and tensor properties are proven through Noether's theorem. Its components, such as the 00 component being the relativistic mass density, are based on convention and symmetry considerations. In GR, the tensor has different forms for different observers due to the principle of general covariance, but conservation laws still hold locally. The inclusion of gravitational energy in the stress tensor is not straightforward, and conservation laws only hold in asymptotically flat spacetimes.
  • #1
kevinferreira
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Hello everyone,

I have some questions concerning the stress-energy-momentum tensor. I know it is a far more general object than the one used in GR, but I guess no one will disagree it plays a far more important role here.

So, firstly, what is the proof of its existence and its tensor properties (I guess I have the same problem with the electromagnetic tensor). Everytime I read something on this it seems that the tensor just falls from the sky to accomplish our wishes. Secondly, the usual way of writing this tensor, e.g. the 00 component being the relativistic mass density, etc., is it purely conventional or not?
Concerning GR, given that this tensor has different forms for different observers (but that's the whole point of the principle of general covariance), they will see differently the effects of the presence of massive bodies (for example an observer in uniform motion will measure a different momentum density). How does this difference is understood in GR?
 
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  • #2
kevinferreira said:
Hello everyone,

I have some questions concerning the stress-energy-momentum tensor. I know it is a far more general object than the one used in GR, but I guess no one will disagree it plays a far more important role here.

So, firstly question, what is the proof of its existence and its tensor properties (I guess I have the same problem with the electromagnetic tensor). Everytime I read something on this it seems that the tensor just falls from the sky to accomplish our wishes. Secondly, the usual way of writing this tensor, e.g. the 00 component being the relativistic mass density, etc., is it purely conventional or not?
Concerning GR, given that this tensor has different forms for different observers (but that's the whole point of the principle of general covariance), they will see differently the effects of the presence of massive bodies (for example an observer in uniform motion will measure a different momentum density). How does this difference is understood in GR?

Those are good questions. One of the questions I have is whether the stress-energy-momentum tensor can always be put in the form of particles and interactions like photons, leptons and quarks and the energy associated with their speed. I assume that the stress tensor never involves gravitational energy, right?
 
  • #3
kevinferreira said:
Hello everyone,

I have some questions concerning the stress-energy-momentum tensor. I know it is a far more general object than the one used in GR, but I guess no one will disagree it plays a far more important role here.

So, firstly question, what is the proof of its existence and its tensor properties (I guess I have the same problem with the electromagnetic tensor). Everytime I read something on this it seems that the tensor just falls from the sky to accomplish our wishes.

No it does not fall from sky. It is basically a tensor quantity that has conserved components following the fact that almost every physical theory must be invariant under a global set of transformations assigned to the Poincare group (translations in space and time and rotations and boosts). The conservation follows Noether theorem by which one can claim that any global symmetry in the theory in consideration has to associate the theory with a conserved quantity called "Noether charge". Note that Poincare group is global (not local).

Secondly, the usual way of writing this tensor, e.g. the 00 component being the relativistic mass density, etc., is it purely conventional or not?

It is sort of conventional. In some sense, you can define it in a way that the component 33 can indicate the energy density. But there are some subtleties involved. Sometimes it happens that your energy stress tensor is not symmetric (does not generally mean that it is not torsion free). Then the description of continuity equation, [itex]∇_{\mu}T^{\mu\nu}=0[/itex] becomes flawed as switching [itex]\mu[/itex] with [itex]{\nu}[/itex] is not allowed. (For example, there is a need for such symmetry to let the conservation of angular momentum hold.) Also one is not allowed to make the component 01 define encode density since it has to have a counterpart (10 component) which means the energy is now a vector quantity embedded in this tensor, again invalid. So for our best practical purposes, let it be defined the way it is.

Concerning GR, given that this tensor has different forms for different observers (but that's the whole point of the principle of general covariance), they will see differently the effects of the presence of massive bodies (for example an observer in uniform motion will measure a different momentum density). How does this difference is understood in GR?

Following principle of general covariance, all components in this tensor are only conserved locally in GR. So to all observers they look the same. Remember that energy-momentum tensor in GR does not always give you conserved charges as there may be interactions between gravitational field and matter which requires transfer of momentum and energy thus destroying their invariance under translations even locally. Instead, one uses some other object called "Landau–Lifgarbagez pseudotensor" to include all conservation laws at least locally to make sure that the theory has a valid description of conservation laws in it. Note also that in GR conservation laws only hold in asymptotically flat space-times which is by itself a big disadvantage for GR as a theory of gravity in generic curved spacetimes.

P
 
  • #4
friend said:
Those are good questions. One of the questions I have is whether the stress-energy-momentum tensor can always be put in the form of particles and interactions like photons, leptons and quarks and the energy associated with their speed. I assume that the stress tensor never involves gravitational energy, right?

You have stress tensor for pure Maxwell theory, remember?
 
  • #5
kevinferreira said:
Concerning GR, given that this tensor has different forms for different observers (but that's the whole point of the principle of general covariance), they will see differently the effects of the presence of massive bodies (for example an observer in uniform motion will measure a different momentum density). How does this difference is understood in GR?

I think this question is the easy part, and the second parenthetical in your quote shows that you already understand it pretty well.

kevinferreira said:
So, firstly question, what is the proof of its existence and its tensor properties (I guess I have the same problem with the electromagnetic tensor). [...] Secondly, the usual way of writing this tensor, e.g. the 00 component being the relativistic mass density, etc., is it purely conventional or not?

This is a foundational question, and foundational questions are always tricky because the answer depends completely on what you take as your initial assumptions, i.e., your definitions and axioms. For instance, if I ask why the Pythagorean theorem is true, you could say it's true because it can be proved from Euclid's five postulates. But you could just as well take Cartesian geometry to define your set of starting assumptions, in which case the Pythagorean theorem would just be an axiom. Here's a relativistic example along these lines: https://www.physicsforums.com/showthread.php?t=534862 [Broken] .

In the case of the stress-energy tensor T, I could start by *defining* it as [itex]T_{ab}=(1/8\pi)G_{ab}[/itex]. Then its existence and tensor properties are automatically established, since those have already been established for the Einstein tensor G. This would be exactly analogous to what we do in Newtonian mechanics when we define the active gravitational mass of a particle as [itex]m_a=gr^2/G[/itex], where g is the gravitational field it produces at a distance r. I can't think of any other way of defining ma -- can you? Note that both the Newtonian definition and the relativistic one are nontrivial, falsifiable statements. The Newtonian one could be falsified, for example, by any experiment that showed a deviation from the 1/r2 behavior of gravitational fields. The relativistic one could be falsified, for example, by any experiment that showed a nonvanishing value of G in a region of vacuum. (Actually, it *has* been falsified in this sense, because we now know we need to add a cosmological constant term.)

In this approach, what remains is to establish the familiar interpretation of T:

(1) [itex]T^{ab}[/itex] equals the flux of four-momentum pa across a surface of constant xb.

(2) In the Newtonian limit, let x0 be the universal time coordinate that everyone agrees on. Then [itex]T^{00}[/itex] is the mass density.

Interpretation 2 follows by taking the weak-field limit of the Schwarzschild metric and comparing it with the Newtonian definition of active gravitational mass. In other words, it follows from the correspondence principle, so any experiment that falsified it would be in conflict with the centuries' worth of observations that had already established the validity of Newtonian gravity within its own domain of applicability.

I would consider 1 to be a theoretical conjecture by Einstein, which was verified by experiment. That is, in the approach I've suggested, where the Einstein field equations are taken to be true by definition, the only way to falsify GR (or actually GR with [itex]\Lambda=0[/itex]) is to falsify statement 1.

Statement 1 is highly theoretically plausible. That is, if experiments falsified 1, then I think it would be hard to salvage GR as a theory of four-dimensional spacetime in which matter determines curvature and curvature determines the geodesics along which material particles move. For example, if you believe in these basic ideas of GR, then energy-momentum has to be a four-vector, i.e., you can't have a scalar energy that acts as a source of gravity. Given these transformation properties of energy-momentum, you can, for example, transform dust from its rest frame to some other frame, and verify statement 1: http://www.lightandmatter.com/html_books/genrel/ch08/ch08.html [Broken] (example 1). This verifies 1 in the case where the matter is dust, up to first order in the velocity relative to the dust's rest frame.

To justify 1 more generally, I think you have to start by observing that the Einstein field equation makes T divergenceless as a matter of geometrical definition. This is what allows you to interpret T as the flux of some quantity that is locally conserved.

As an alternative, Carroll gives a treatment in which statement 1 is taken as a definition, in which case the Einstein field equations are not simply true as a matter of definition: http://ned.ipac.caltech.edu/level5/March01/Carroll3/Carroll1.html
 
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  • #6
One way I ran across recently for deriving the stress energy tensor formally for a swarm of particles is that it's the tensor product of the number-flux vector of the swarm and the energy-momentum 4-vector of each particle.http://web.mit.edu/edbert/GR/gr2b.pdf has a little bit in the same vein, though the treatment I really liked was in google books (but I'm not sure where).

You might have to look up "number-flux 4 vector",or ask more about it if it's unfamiliar, but I'm going to wait for questions rather than try to volunteer an explanation.

Swarms of particles are not the most general model, but serve IMO as reasonable motivation for constructing the more general stress-energy tensor. The swarm of particle model doesn't handle fields, but there isn't any problem including them in the stress-energy tensor.
 
  • #7
Well, if I'm right, the stress-energy-momentum tensor does not involve potentials or fields of the gravitational force itself. That would lead to an infinite series of corrections as the gravitational field contributed to the tensor which contributes to the curvature, which contributes to the tensor again and again. Therefore, I assume that that stress tensor is only due to the other 3 forces of the strong, weak, and electromagnetic forces. But these 3 forces and all their effects can be accounted for in quantum field theory. So my question is what is the stress-energy tensor in terms of the quantum field theory of these 3 forces and fields? Is that just a higher dimensional version of the energy in the fields? Then how is that become a tensor?
 
  • #8
friend said:
Well, if I'm right, the stress-energy-momentum tensor does not involve potentials or fields of the gravitational force itself. That would lead to an infinite series of corrections as the gravitational field contributed to the tensor which contributes to the curvature, which contributes to the tensor again and again.

A side note not totally related to this question; infinite series of corrections are not necessarily a bad thing, if the series is convergent. If it isn't, as long as one pays attention to the radius of convergence it is still useful.
 
  • #9
Altabeh said:
Instead, one uses some other object called "Landau–Lifgarbagez pseudotensor" to include all conservation laws at least locally to make sure that the theory has a valid description of conservation laws in it. Note also that in GR conservation laws only hold in asymptotically flat space-times which is by itself a big disadvantage for GR as a theory of gravity in generic curved spacetimes.
P

I understand this lack of conservation laws on a curved space, present on GR. And about this Landau-Lifgarbagez pseudo-tensor, does it express something only locally? If not, how does it relate to the curvature and the presence of momentum/mass/energy densities?
Thanks for your answer!
 
  • #10
bcrowell said:
I think this question is the easy part, and the second parenthetical in your quote shows that you already understand it pretty well.
But I'm still pretty confused with something: if different observers express the energy-mom tensor differently, and Einstein's equations hold on each of them equally, they will also perceive differently the spacetime structure. It seems odd that this doesn't lead to contradictions, but on the other hand we're used to this kind of things in special rerlativity too... Also, can we include on this set of observers non-inertial observers?

bcrowell said:
To justify 1 more generally, I think you have to start by observing that the Einstein field equation makes T divergenceless as a matter of geometrical definition. This is what allows you to interpret T as the flux of some quantity that is locally conserved.
I can see from the definition you gave above in terms of the Einstein tensor (that is simply Einstein's eqns, just as you did with Newton's) that T becomes divergenceless. But I don't understand that this "allows' us to interpret T as the flux of some locally conserved quantity, I think about this as being true only the other way around, that is, if you have some locally conserved quantity then you can build a divergenceless object. But then, from your explanation, I kinda see the 'intuition' behind this construction and what you said.
Also, I don't see why this divergenceless property is useful. You obtain 4 covariantly constant quantities (for each [itex]\nu[/itex] in [itex]\nabla_{\mu}T^{\mu\nu}=0[/itex]), which means that they are Lorentz scalars even in a curved spacetime... So what?
Thanks for your answer!
 
  • #11
kevinferreira said:
But I'm still pretty confused with something: if different observers express the energy-mom tensor differently, and Einstein's equations hold on each of them equally, they will also perceive differently the spacetime structure. It seems odd that this doesn't lead to contradictions, but on the other hand we're used to this kind of things in special rerlativity too... Also, can we include on this set of observers non-inertial observers?
Yes, you can include non-inertial observers and coordinate systems.

The key to understanding this, at least for me, was to recognize the difference between coordinate values and geometric (covariant or invariant) objects. Although different observers using different coordinate systems will express the geometric objects using different coordinate values, they are in fact talking about the same geometric objects. Because they are talking about the same geometric objects they never get contradictions, although their descriptions vary.

The same thing happens with ordinary vectors in flat spacetime. Alice can use Cartesian coordinates, Bob can use rotated Cartesian coordinates, and Chris can use spherical coordinates to describe a set vectors and their sums and products. As long as they all do their math correctly they will not get any contradictions, although they will use different numbers to describe the same things.

The only difficult thing is to realize that energy, by itself, is not one of these geometric objects. Similarly with momentum, etc.
 
  • #12
DaleSpam said:
Yes, you can include non-inertial observers and coordinate systems.

The key to understanding this, at least for me, was to recognize the difference between coordinate values and geometric (covariant or invariant) objects. Although different observers using different coordinate systems will express the geometric objects using different coordinate values, they are in fact talking about the same geometric objects. Because they are talking about the same geometric objects they never get contradictions, although their descriptions vary.

The same thing happens with ordinary vectors in flat spacetime. Alice can use Cartesian coordinates, Bob can use rotated Cartesian coordinates, and Chris can use spherical coordinates to describe a set vectors and their sums and products. As long as they all do their math correctly they will not get any contradictions, although they will use different numbers to describe the same things.

The only difficult thing is to realize that energy, by itself, is not one of these geometric objects. Similarly with momentum, etc.

Aah, now I see, I didn't think about that, but you're absolutely right, of course, this is the whole point of general covariance, of course.
Thanks!
 
  • #13
kevinferreira said:
I can see from the definition you gave above in terms of the Einstein tensor (that is simply Einstein's eqns, just as you did with Newton's) that T becomes divergenceless. But I don't understand that this "allows' us to interpret T as the flux of some locally conserved quantity, I think about this as being true only the other way around, that is, if you have some locally conserved quantity then you can build a divergenceless object. But then, from your explanation, I kinda see the 'intuition' behind this construction and what you said.
Also, I don't see why this divergenceless property is useful. You obtain 4 covariantly constant quantities (for each [itex]\nu[/itex] in [itex]\nabla_{\mu}T^{\mu\nu}=0[/itex]), which means that they are Lorentz scalars even in a curved spacetime... So what?
Thanks for your answer!

Let's say you are able to make an accurate census each day of how many U.S. pennies exist in Canada and the U.S., and say the pennies always stay within those two countries. If, on a given day, the number of pennies in the U.S. increases by 738, you should be able to verify that the number in Canada changes by -738. The two numbers have to add up to zero, because pennies are conserved. You can infer that that is the net number of pennies that crossed the border during that 24-hour period. That is, you can interpret the 738 as a flux of pennies.

If you try to do it with people instead of pennies, it doesn't work. That's because people aren't conserved. They're born, and they die. The populations of the U.S. and Canada can change both because of births and deaths and because people are crossing the border. The change in population from day to day cannot be interpreted as a flux across the border.

The divergenceless property of T says that energy-momentum is (locally) conserved. This is closely analogous to the continuity equation for electromagnetism, which says that charge is conserved: [itex]\nabla\cdot J = -\partial\rho/\partial t[/itex], or [itex]\nabla_a J^a=0[/itex].
 
  • #14
kevinferreira said:
So, firstly, what is the proof of its existence and its tensor properties (I guess I have the same problem with the electromagnetic tensor). Everytime I read something on this it seems that the tensor just falls from the sky to accomplish our wishes. Secondly, the usual way of writing this tensor, e.g. the 00 component being the relativistic mass density, etc., is it purely conventional or not?

It does fall from the sky if you have an action, and the action falls from the sky in the sense that you can take it as a definition of the theory. https://www.physicsforums.com/showpost.php?p=4213595&postcount=1

In specifying an action for general relativity, we of course put in the Einstein-Hilbert term. However, without specifying what matter there is - ie. the form of the enery-momentum tensor and the equations of motion for that matter - the Einstein equation is meaningless or "tautological" - like F=ma without saying what F is. One way of specifying these additional quantities needed to define GR is by specifying the matter action - eg. the action of the electrons, quarks etc (or if you don't need such detailed modelling, you can use less detailed matter such as a perfect fluid). By the principle of equivalence that SR is an excellent approximation locally, the matter action should couple to the metric and not its derivatives ("minimal coupling"), and the GR form should be the general covariant form of the SR form.

In GR, in arbitrary coordinates, the components don't have any special meaning. However, since in GR we can locally make coordinates to look like SR, then in those coordinates the local components have their SR meaning.
 
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  • #15
GR, like Newtonian mechanics, can be derived as a Lagrangian theory.

Hence, knowing the Lagrangian density (or the action) of the matter fields is all that one needs to get the stress energy tensor.

I will assume people know what a Lagrangian density is (at least well enough) and not explain it further unless asked. (I'm sorry, but I don't know people's background here, I have to guess.)

Wald has a brief discussion of the process.

To devlop GR as a Lagrangian theory, first you start out without matter fields, and you find that the Einstein-Hilbert action is just sqrt(R), R being the Ricci scalar.

There are other, more complex, actions that people use, but this simple action is the basis of GR, anticipating the question of "why this action".

Applying variational principles one wishes to find the metric [itex]g_{ab}[/itex] that makes the action stationary. One gets the usual Euler-lagrange equatios from this, which basically say that G_ab = 0, where G is the Einstein Tensor.
To add matter into the theory, one writes [itex]L_{tot} = L_{space} + \alpha L_{matter}[/itex], where I've used L for the Lagrangian density.

Then applying variational principle as before, one gets [itex]G_{ab}[/itex] = (some constant) [itex]T_{ab}[/itex] where T_{ab} is naturally defined as the variation of the Lagrangian density with respect to the metric coefficeints, [itex]g_{ab}[/itex]. As mentioned in some other thread, this is just

[itex]T_{ab} = \frac{\delta L}{\delta g_{ab}}[/itex]

[add]The related thread is:

https://www.physicsforums.com/showthread.php?t=661700
 
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  • #16
Kevin: I'm not sure the discussion so far answers your real question: pervect and Crowell addressed the SET admirably...I continue learn a lot from their posts.

If they don't exclaim 'idiot' or some such about this post and this is in fact of interest, I can provide some other details.

Your question:

Concerning GR, given that this tensor has different forms for different observers (but that's the whole point of the principle of general covariance), they will see differently the effects of the presence of massive bodies (for example an observer in uniform motion will measure a different momentum density). How does this difference is understood in GR?


But I wonder if this interests you:


The "amount of gravity produced by an object" is frame-invariant; it doesn't matter what your state of motion is relative to the object.


In GR the stress–energy tensor is the source of gravitation and it is not frame-invariant.


The answer to the discrepancy between the previous discussion and these statements is here:

From Misner,Thorne and Wheeler:


… nowhere has a precise definition of the term “gravitational field” been
given --- nor will one be given. Many different mathematical entities are
associated with gravitation; the metric, the Riemann curvature tensor, the
curvature scalar … Each of these plays an important role in gravitation
theory, and none is so much more central than the others that it deserves the name “gravitational field.”

[That 'the amount of gravity produced by an object' is frame invariant is easy to prove:
Right now I am in some frame approaching the speed of light. Yet in my frame all is normal. Another way to say this: no matter how fast an object moves it will not become a black hole. ]
 
  • #17
I would say the stress-energy tensor as a whole is frame invariant, this comes from its tensor nature - it's a geometric object.

Wiki seems to offer the same definition (though their discussion is nontelativistic, so the details don't strictly apply here). But they also say a quantity is frame invariant if it transforms correctly.

http://en.wikipedia.org/w/index.php?title=Objectivity_(frame_invariance)&oldid=524091607

Any spatial vector field u that transforms such that ... is objective

The individual components of the stress-energy tensor are not frame-invariant, however.

This is similar to the way that the energy-momentum 4 vector is frame-invariant, but energy is not.

I don't know how one would define "the amount of gravity" produced by an object. If one looks at the residual velocities present after a high speed flyby, though, GR predicts that the residual velocities observed after a flyby will increase as the flyby velocity increases for an object of the same rest mass.

http://adsabs.harvard.edu/abs/1985AmJPh..53..661O

If a heavy object with rest mass M moves past you with a velocity comparable to the speed of light, you will be attracted gravitationally towards its path as though it had an increased mass. If the relativistic increase in active gravitational mass is measured by the transverse (and longitudinal) velocities which such a moving mass induces in test particles initially at rest near its path, then we find, with this definition, that Mrel=γ(1+β^2)M.

If measuring the velocites induced by a flyby is at all comparable to your idea of "amount of gravity", then the "amount of gravity" does depend on your velocity.
 
  • #18
Naty1 said:
[That 'the amount of gravity produced by an object' is frame invariant is easy to prove:
Right now I am in some frame approaching the speed of light. Yet in my frame all is normal. Another way to say this: no matter how fast an object moves it will not become a black hole. ]

Yes, I see that, all objects used in Einstein equations (and the associated mathematical treatment) have an 'independet reality', just like a vector in euclidean space have a unique defining direction and magnitude no matter how we wish to represent it via our coordinates. So, I just have to think that the Riemann curvature tensor, the Ricci tensor, the metric tensor, etc. have a mathematically objective reality on spacetime to get to the conclusion with the help of Einstein's to see that the energy-momentum tensor shares the same properties.

But...
If I'm not mistaken, all these objects are defined locally, i.e. through their action on elements of the tangent space to a point (I take here the definition of tensor as a function acting on any number of cartesian products between the tangent and the cotangent spaces).
Therefore, even if we may define a tensorfield in every point of our spacetime as the collection of these definitions at each tangent space for each point, how can GR tell us something about large scale phenomena if all objects in our treatment are defined on tangent spaces, which are nothing else but 'nice' and local aproximations of our manifold?
Also, another thing that bothers me is that since locally the laws of special relativity hold, and we can 'transform away' gravity by just considering an accelerated frame (just as Einstein presented it in his 1916 paper), how is it that this locality and the locality used to define our tensors may in the end tell us something about the manifold itself?
This bothers me alot, we use the word 'locally' everywhere, but in the end we can actually tell something about spacetime itself.
Is it implicit in our definitions and mathematical treatment of the theory that what we actually do is the same as for example the way we would study the curvature of a graph, just observe the tangent lines at each point and then compare them in order to know how 'non-flat' is our graph? I think this might be somehow true, as the Riemann and Ricci tensors' components are calculated in some particular coordinates with the derivatives of the metric components...
And I also remember having done an exercise where we show that locally the metric is the Minkowski flat metric up to a second order term, related with the curvature tensors. But again, this 'locally' is not of the same kind as the previous ones, or is it?

I'm sorry I'm getting out of the topic, but I think all this has to do with the energy-momentum tensor, it's the other side of the equation!
 
  • #19
kevinferreira said:
But...
If I'm not mistaken, all these objects are defined locally, i.e. through their action on elements of the tangent space to a point (I take here the definition of tensor as a function acting on any number of cartesian products between the tangent and the cotangent spaces).
Therefore, even if we may define a tensorfield in every point of our spacetime as the collection of these definitions at each tangent space for each point, how can GR tell us something about large scale phenomena if all objects in our treatment are defined on tangent spaces, which are nothing else but 'nice' and local aproximations of our manifold?
Also, another thing that bothers me is that since locally the laws of special relativity hold, and we can 'transform away' gravity by just considering an accelerated frame (just as Einstein presented it in his 1916 paper), how is it that this locality and the locality used to define our tensors may in the end tell us something about the manifold itself?
This bothers me alot, we use the word 'locally' everywhere, but in the end we can actually tell something about spacetime itself.
Is it implicit in our definitions and mathematical treatment of the theory that what we actually do is the same as for example the way we would study the curvature of a graph, just observe the tangent lines at each point and then compare them in order to know how 'non-flat' is our graph? I think this might be somehow true, as the Riemann and Ricci tensors' components are calculated in some particular coordinates with the derivatives of the metric components...
And I also remember having done an exercise where we show that locally the metric is the Minkowski flat metric up to a second order term, related with the curvature tensors. But again, this 'locally' is not of the same kind as the previous ones, or is it?

The first "locally" just means that the objects in the theory are tensor fields - they exist at every point on the manifold, and act on tangent vectors. (Actually, I've never seen this called "locally" until now.)

The second "locally the metric is the Minkowski flat metric up to a second order term" shows that the EP is true only at a point, and only up to first derivatives of the metric. It's the second derivatives that are crucial in distinguishing curved and flat spacetime. This is why in writing the matter action that Pervect and I talked about in posts 14 and 15, the matter fields must be coupled to the metric and not its derivatives. This prescription from the equivalence principle is also called "minimal coupling".

When you differentiate the full GR action LEH+Lmatter wrt the various fields, you then get the Einstein field equation with the correct definition of the stress tensor, and the equations of motion for the various matter fields. Because the equations came from an action in which matter was minimally coupled to the metric, the stress tensor derived in this way obeys the EP in the sense that in coordinates in which the metric (but not its second derivatives) have the same form as a Lorentz inertial frame, the components of the stress-energy tensor then have their SR meaning.
 
  • #20
kevinferreira said:
I understand this lack of conservation laws on a curved space, present on GR. And about this Landau-Lifgarbagez pseudo-tensor, does it express something only locally? If not, how does it relate to the curvature and the presence of momentum/mass/energy densities?
Thanks for your answer!

Good question. Well, the general approach is based on a covariant formalism, providing one with global conservation laws in asymptotically flat spacetimes. For example, it can be used to give the mass of an isolated black-hole (which is asymptotically flat). A more recent and general approach can be found in arXiv:1202.1905.

LL pseudo-potential is related to curvature via Einstein field equations with some modifications. More technically, it is related with Ricci tensor density and scalar curvature density through an identity derived according to Noether's prescription for finding the conserved quantities of a Lagrangian which is a scalar density.

I hope this is enough. If you need more details, we can discuss it.

P
 
  • #21
atyy said:
The first "locally" just means that the objects in the theory are tensor fields - they exist at every point on the manifold, and act on tangent vectors. (Actually, I've never seen this called "locally" until now.)
Well, the tangent space is defined pointwise on the manifold, so that it describes linearly and 'locally' the manifold... This was the sense I was trying to give to it. What bothers me is that this pointwise definition is implicit on tensors, and then in the end they can give us some information about non-pointwise properties of the manifold... Or I'm confused and maybe they don't, after all when we say that test particles follow geodesics, we are just saying they follow a particular set of points on spacetime, and maybe these points form a geodesic by some combination of pointwise properties. Hmm...

atyy said:
When you differentiate the full GR action LEH+Lmatter wrt the various fields, you then get the Einstein field equation with the correct definition of the stress tensor, and the equations of motion for the various matter fields. Because the equations came from an action in which matter was minimally coupled to the metric, the stress tensor derived in this way obeys the EP in the sense that in coordinates in which the metric (but not its second derivatives) have the same form as a Lorentz inertial frame, the components of the stress-energy tensor then have their SR meaning.

Aah, I see here the whole beauty of starting from the action with this minimal coupling which lead us to the EP... Hmm, what do you mean more precisely by the 'SR meaning' of the components of the stress-energy tensor?
 
  • #22
Altabeh said:
Good question. Well, the general approach is based on a covariant formalism, providing one with global conservation laws in asymptotically flat spacetimes. For example, it can be used to give the mass of an isolated black-hole (which is asymptotically flat). A more recent and general approach can be found in arXiv:1202.1905.

LL pseudo-potential is related to curvature via Einstein field equations with some modifications. More technically, it is related with Ricci tensor density and scalar curvature density through an identity derived according to Noether's prescription for finding the conserved quantities of a Lagrangian which is a scalar density.

I hope this is enough. If you need more details, we can discuss it.

P

Ok, I see, I'll check on that. Thanks a lot for your help!
 
  • #23
kevinferreira said:
Well, the tangent space is defined pointwise on the manifold, so that it describes linearly and 'locally' the manifold... This was the sense I was trying to give to it. What bothers me is that this pointwise definition is implicit on tensors, and then in the end they can give us some information about non-pointwise properties of the manifold... Or I'm confused and maybe they don't, after all when we say that test particles follow geodesics, we are just saying they follow a particular set of points on spacetime, and maybe these points form a geodesic by some combination of pointwise properties. Hmm...

Well, just think of something simple like position as a function of time in classical Newtonian mechanics. If the function is analytic, from its derivatives at a point, through Taylor series, you can get the function away from that point. In this sense, higher and higher derivatives are more and more "nonlocal" (although strictly speaking, the derivatives are all well defined at that point, which is the point of calculus and taking limits). The rough idea is that the first derivative contains the difference of two points, so it is more "nonlocal" that the value of the function itself at that point. And of course, once you have specified the function at every point, you have also specified all the derivatives.

kevinferreira said:
Aah, I see here the whole beauty of starting from the action with this minimal coupling which lead us to the EP... Hmm, what do you mean more precisely by the 'SR meaning' of the components of the stress-energy tensor?

I think of minimal coupling as another name for the EP. The SR (special relativity) meaning is just that in flat spacetime, and especially in coordinates where the flat spacetime metric is diag(-1,1,1,1), we understand the stress tensor components to have meanings such as T00 is the "energy density". When we go to arbitrary coordinates in curved spacetime, it isn't clear why T00 would still be the "energy density". So to get the meaning of the stress tensor components, we take advantage of the fact that locally you can have "flat spacetime" as long as you don't look at higher derivatives, and it is in those coordinates that the stress tensor components have their traditional SR meaning.
 
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  • #24
kevinferreira said:
Well, the tangent space is defined pointwise on the manifold, so that it describes linearly and 'locally' the manifold... This was the sense I was trying to give to it.
Not sure what you mean by the tangent space describes the manifold M locally at some p in M. Tp(M) is a subset of the tangent bundle of M; it is not a neighborhood of p. Local properties are expressed in terms of neighborhoods of points and / or bases for topologies.
 
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  • #25
atyy said:
Well, just think of something simple like position as a function of time in classical Newtonian mechanics. If the function is analytic, from its derivatives at a point, through Taylor series, you can get the function away from that point. In this sense, higher and higher derivatives are more and more "nonlocal" (although strictly speaking, the derivatives are all well defined at that point, which is the point of calculus and taking limits). The rough idea is that the first derivative contains the difference of two points, so it is more "nonlocal" that the value of the function itself at that point. And of course, once you have specified the function at every point, you have also specified all the derivatives.
That makes sense, it is true that one says 'the derivative of f at x' even though in the definition of that object one has to evaluate f at a neighbour point of x (with the subsequent limit). It seems more clear now!

atyy said:
Well
I think of minimal coupling as another name for the EP. The SR (special relativity) meaning is just that in flat spacetime, and especially in coordinates where the flat spacetime metric is diag(-1,1,1,1), we understand the stress tensor components to have meanings such as T00 is the "energy density". When we go to arbitrary coordinates in curved spacetime, it isn't clear why T00 would still be the "energy density". So to get the meaning of the stress tensor components, we take advantage of the fact that locally you can have "flat spacetime" as long as you don't look at higher derivatives, and it is in those coordinates that the stress tensor components have their traditional SR meaning.
Yes, that is what I was thinking about, just wanted to be sure of it completely. It's amazing how we could think that Einstein's equations are plane and simple when looking at them, and think that we can forget about all the rest, but in fact all fundamental principles and axioms of GR are somehow encoded on those equations. I feel amazed! Thanks for your help!
 
  • #26
WannabeNewton said:
Not sure what you mean by the tangent space describes the manifold M locally at some p in M. Tp(M) is a subset of the tangent bundle of M; it is not a neighborhood of p. Local properties are expressed in terms of neighborhoods of points and / or bases for topologies.

Indeed, Tp(M) is not a neighbourhood of p, but you can find a local homeomorphism (that is even a local diffeomorphism, I think...) between a neighbourhood of p in M and a neighbourhood of the origin on the tangent space. It is called the exponential map and is very useful in Lie group theory. You may want to check http://en.wikipedia.org/wiki/Exponential_map, the part about Riemannian geometry. This has also something to do with Riemann normal coordinates, although I don't want to go on that as I haven't revisited that part of my lectures yet.
You can see it says it kinda helps to understand how the tangent space may be seen as a 'linearisation' of the manifold. This makes sense if you think about a sphere and the tangent plane at the north pole. You can imagine that even if the only point of contact between the sphere and the plane is the north pole, you may describe very well the sphere around the pole by considering points on the tangent plane. This is my way of thinking about it.
 
  • #27
kevinferreira said:
This is my way of thinking about it.
Without getting side - tracked from the thread, I think the issue here is just what you mean by "local". The linearity part is fine but there are many "local" properties of and on manifolds that can't just be described by a tangent space at a point (for example how the co-variant derivative of a vector field along a direction depends only on the element of the tangent space at the given point corresponding to that direction whereas the lie derivative of the vector field along another requires knowledge of the other vector field in a neighborhood of the point).
 
  • #28
kevinferreira said:
Indeed, Tp(M) is not a neighbourhood of p, but you can find a local homeomorphism (that is even a local diffeomorphism, I think...) between a neighbourhood of p in M and a neighbourhood of the origin on the tangent space. It is called the exponential map and is very useful in Lie group theory. You may want to check http://en.wikipedia.org/wiki/Exponential_map, the part about Riemannian geometry. [...]
You can see it says it kinda helps to understand how the tangent space may be seen as a 'linearisation' of the manifold. This makes sense if you think about a sphere and the tangent plane at the north pole. You can imagine that even if the only point of contact between the sphere and the plane is the north pole, you may describe very well the sphere around the pole by considering points on the tangent plane. This is my way of thinking about it.

Not being an expert of GR or DiffGeo*, but I think a tangent space to a diff. manifold is not a topological space, merely an algebraic construction, a vector space (it has no neighbourhoods). And related to Lie groups, the exponential mapping takes indeed an infinite set of points from the Lie group, to be precise from an open neighbourhood of the origin (neutral element) to an infinity of vectors in the Lie algebra, in the general case and from one point from the Lie group to one vector in the Lie algebra.

*My exposure to both GR and DiffGeo was minimal a while ago (and has not improved significantly in the mean time), the course was based on the 75 page brochure by Dirac! :D
 
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  • #29
atyy said:
It does fall from the sky if you have an action, and the action falls from the sky in the sense that you can take it as a definition of the theory. https://www.physicsforums.com/showpost.php?p=4213595&postcount=1
[...]

I wouldn't say that, nothing really comes from the sky, not even the action (once you have the action, you definitely have a method to get an energy-momentum 4 vector/tensor). Every action integral has at least 3,4 justifying assumptions as to why that Lagrangian and not another one. Nothing is random in physics.
 
  • #30
pervect: Your post #17 was helpful.

In general I depend on you experts for current usage of terminology as well as physical interpretations of detailed mathematics. [I've been out of school way too long to try and catch up!]

from your post:

I don't know how one would define "the amount of gravity" produced by an object...If measuring the velocities induced by a flyby is at all comparable to your idea of "amount of gravity", then the "amount of gravity" does depend on your velocity.


That term comes from PeterDonis and several old threads where you and DocAl
and probably others were kind enough to help me understand spacetime 'gravitational curvature'. I came away with the understanding ['real'] gravitational observations relating to a rapidly moving massive body can be answered as if the body is stationary so that relative velocities are NOT considered as part of gravitational curvature...

One aspect of THAT logic is the one I posted already: fast moving particles don't become black holes. A related perspective would be that for a single electron, as an example, the rest energy density of the electron is the only thing that causes spacetime gravitational curvature. The kinetic energy is frame-dependent, just as the velocity is...and does not contribute.

So 'velocity' does not yet enter into my understanding of 'the amount of gravity'.


Here is how docAl explained it from an old thread [ edited by me for brevity]:

If a flat sheet of graph paper represents two dimensional space without gravity, with the introduction of gravitation the paper itself becomes curved. [Curvature that cannot be "flattened" without distortion.] Gravitational "spacetime curvature" refers to this curvature of the graph paper, regardless of observer, whereas visible/perceived curvature in space is related to distorted, non-square grid lines drawn on the curved graph paper, and depends on the frame choice of the observer..."

So additional relative velocity DOES cause physical effects,as your quote shows, but THAT curvature was not considered 'gravitational curvature'...That is, the 'amount of gravity' ...

So while I believe the above is self consistent, I really do not know if such terminology is
generally understood that way in these forums. And when I first posted in this thread I was unsure if the OP, got the answer he thought he did.

PS: best thread on gravity in a while!
 
  • #31
kevin: You might find this discussion of interest: Spacetime Curvature Observer and/or Coordinate Dependent?

https://www.physicsforums.com/showthread.php?t=596224
April, 2012
...If by "gravity" you mean "particular effects of gravity", then yes. As you point out, particular effects of gravity on particular observers will always be dependent on the observer's 4-velocity…. this is a question of terminology, not physics. Whether or not "spacetime curvature" is observer-dependent depends on what you define "spacetime curvature" to mean.

edit: I just came across this John Baez/Ted Bunn discussion comment [and if I were the least bit organized, would have included it in my original post]:

"In general relativity, knowing all about the sources (the stress-energy tensor T) isn't enough to tell you all about the curvature." which complements the MTW quote.
 
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  • #32
dextercioby said:
Not being an expert of GR or DiffGeo*, but I think a tangent space to a diff. manifold is not a topological space, merely an algebraic construction, a vector space (it has no neighbourhoods). And related to Lie groups, the exponential mapping takes indeed an infinite set of points from the Lie group, to be precise from an open neighbourhood of the origin (neutral element) to an infinity of vectors in the Lie algebra, in the general case and from one point from the Lie group to one vector in the Lie algebra.

Allow me to disagree, every vector space may be trivially defined as a topological space, and hence also the tangent space. You see, you can use the notion of norm on the vector space to have a notion of distance, and with the distance you can build a topology. From that you may trivially see it as a manifold. A vector space is the most nice manifold you may ask for.
 
  • #33
Naty1 said:
So additional relative velocity DOES cause physical effects,as your quote shows, but THAT curvature was not considered 'gravitational curvature'...That is, the 'amount of gravity' ...

I found this quite confusing. I think the disturbing cause is that we are considering only energy as the cause of gravity, and that is not true, energy is not a Lorentz scalar. Whenever you may want to consider velocity, you will see that you add a momentum density to the energy-momentum tensor, but you will also change the relativistic mass density, so that in the end (just like with the energy momentum 4 vector) nothing changes in general. I wonder if this is a correct view of it.
 
  • #34
kevinferreira said:
Allow me to disagree, every vector space may be trivially defined as a topological space, and hence also the tangent space. You see, you can use the notion of norm on the vector space to have a notion of distance, and with the distance you can build a topology [...]

http://en.wikipedia.org/wiki/Tangent_space Both definitions here (first and second) ascribe an algebraic (i.e. according to the axioms here http://en.wikipedia.org/wiki/Vector_space) character to the tangent space in a point x of a general manifold. Where does the norm (which would induce the topology on T_x (M)) come from ?

Your first sentence induces the set inclusion

{vector spaces} [itex] \subset [/itex] {topological spaces}

which is not not correct (the axioms of a vector space don't mention a norm, so there wouldn't be any norm-induced topology
).

The right set connection is:

{topological vector spaces} = {vector spaces} [itex] \cap [/itex] {topological spaces}
 
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  • #35
nothing changes in general. I wonder if this is a correct view of it.

I found that confusing ! really...

Let's consider an object moving in free fall relative to an observer following a particular path. If an identical particle at a different velocity, or an identical particle with the same velocity but also angular momentum then passes the observer, the particles will in general follow three different paths.

That's the physics ,I think we can agree.

In the view I gave, the second particle with angular momentum changes gravitational spacetime curvature relative to the first; the third particle with only additional velocity has a different 'visible curvature'...but it is not part of 'the amount of gravity'.

That is just a convention, but one that seems to make sense to me regarding fast moving particles not becoming black holes.
 
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<h2>1. What is the stress-energy-momentum tensor?</h2><p>The stress-energy-momentum tensor is a mathematical object in general relativity that describes the distribution of energy, momentum, and stress in a given region of spacetime. It is a 4x4 matrix that contains 10 independent components, representing different physical quantities such as mass, energy density, pressure, and momentum density.</p><h2>2. How is the stress-energy-momentum tensor related to Einstein's field equations?</h2><p>The stress-energy-momentum tensor is a key component in Einstein's field equations, which describe the relationship between the curvature of spacetime and the distribution of matter and energy within it. The stress-energy-momentum tensor appears on the right-hand side of the equations, representing the source of gravity.</p><h2>3. What is the role of the stress-energy-momentum tensor in general relativity?</h2><p>The stress-energy-momentum tensor plays a crucial role in general relativity as it is the source of the gravitational field. It describes the distribution of matter and energy in a given region of spacetime, and this distribution determines the curvature of spacetime according to Einstein's field equations.</p><h2>4. How is the stress-energy-momentum tensor calculated?</h2><p>The stress-energy-momentum tensor is calculated using the energy-momentum tensor, which describes the energy and momentum of a physical system. The stress-energy-momentum tensor is then derived from the energy-momentum tensor by including the effects of pressure and stress.</p><h2>5. What are some real-world applications of the stress-energy-momentum tensor?</h2><p>The stress-energy-momentum tensor has many applications in astrophysics and cosmology, such as in the study of black holes, gravitational waves, and the evolution of the universe. It is also used in engineering and technology, such as in the design of spacecraft and in the development of new theories of gravity.</p>

1. What is the stress-energy-momentum tensor?

The stress-energy-momentum tensor is a mathematical object in general relativity that describes the distribution of energy, momentum, and stress in a given region of spacetime. It is a 4x4 matrix that contains 10 independent components, representing different physical quantities such as mass, energy density, pressure, and momentum density.

2. How is the stress-energy-momentum tensor related to Einstein's field equations?

The stress-energy-momentum tensor is a key component in Einstein's field equations, which describe the relationship between the curvature of spacetime and the distribution of matter and energy within it. The stress-energy-momentum tensor appears on the right-hand side of the equations, representing the source of gravity.

3. What is the role of the stress-energy-momentum tensor in general relativity?

The stress-energy-momentum tensor plays a crucial role in general relativity as it is the source of the gravitational field. It describes the distribution of matter and energy in a given region of spacetime, and this distribution determines the curvature of spacetime according to Einstein's field equations.

4. How is the stress-energy-momentum tensor calculated?

The stress-energy-momentum tensor is calculated using the energy-momentum tensor, which describes the energy and momentum of a physical system. The stress-energy-momentum tensor is then derived from the energy-momentum tensor by including the effects of pressure and stress.

5. What are some real-world applications of the stress-energy-momentum tensor?

The stress-energy-momentum tensor has many applications in astrophysics and cosmology, such as in the study of black holes, gravitational waves, and the evolution of the universe. It is also used in engineering and technology, such as in the design of spacecraft and in the development of new theories of gravity.

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