QFT with respect to general relativity

In summary, there are several theories attempting to combine general relativity and quantum field theory, but none have been widely accepted yet. The graviton, a particle associated with the gravitational force, can be described as a quantized deviation from flat space. String theory is one of the few consistent approaches to quantum gravity, but it lacks the full dynamical properties of general relativity. Other non-perturbative approaches, such as loop quantum gravity, attempt to address this issue. The search for a theory of quantum gravity is primarily focused on understanding the behavior of space-time at the Planck scale.
  • #1
jacksonb62
21
0
After recently researching about Quantum Field Theory and more specifically gravitons, I am slightly confused with how this theory of the gravitational force fits in with general relativity. I know it hasn't disproved it so there must be some connection. Do gravitons in 11 dimensions cause curvature in 4 dimensional space-time that we observe as gravity? I've been thinking hard about this one and its been stumping me
 
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  • #2
We don't yet have a generally-accepted theory that combines general relativity and quantum field theory. People are working on different approaches (e.g. string theory, loop quantum gravity) but none of them has won out.
 
  • #3
So string theory is postulating that gravitons are closed loops that can move between branes correct? Would this possibly explain why they would cause curvature in the 4 dimensions that we can observe? If the particles travel between extra dimensions it seems to me that the effects in our 4 dimensions would then be what we observe as general relativity. Just a thought
 
  • #4
A few comments in lieu of a comprehensive explanation...

If you have read about general relativity, you may be aware that the curvature of space is described by the metric, and the metric is described by a tensor field.

In quantum field theory, particles (like the graviton) are associated with fields; they arise by applying the laws of quantum mechanics, such as the uncertainty principle, to the field.

The original way to get a quantum theory of gravitons, as pioneered e.g. by Feynman, is as follows: You take the dynamical metrical field of general relativity. You express it as a deviation from the constant metric of flat space (Minkowski space). Then you treat this deviation itself as the graviton field.

From this perspective, the graviton is a quantized deviation from flat space.

You mention 11 dimensions and string theory. Well, before we get to string theory, let's talk about 11 dimensions. The original 11-dimensional theory was the 11-dimensional form of "supergravity" (which can also be defined for a lower number of dimensions). In supergravity, you have an 11-dimensional metric, an extra "3-form" field that is a generalized version of the electromagnetic field, and then a "gravitino" field which is a matter (fermion) field. So at the quantum level, you have the 11-dimensional graviton (which can be defined in the way I mentioned above), an 11-dimensional photon-like gauge boson, and an 11-dimensional fermion.

If you were trying to get the real world out of 11-dimensional supergravity, you would probably treat 7 of the dimensions as "compact" or "closed", with a radius much less than that of an atomic nucleus. Fundamentally, you still only have the graviton, the 3-form field, and the gravitino. However, the way that e.g. the graviton manifests itself depends on whether it's traveling in one of the extra, compact, closed directions, or whether it's traveling in one of the 3 "large" directions of space. Gravitons traveling in the large directions show up as gravity in 3 dimensions, while gravitons circulating in the compact directions can show up as other forces. This was part of the agenda of pre-string "Kaluza-Klein" unification efforts - the other forces would be explained as resulting from higher-dimensional gravity. (That idea goes back to about 1921.)

In M-theory, along with the fields I've described, you have "M-branes" (of 2 and 5 dimensions) which interact with the graviton, the 3-form, and the gravitino fields. A string is really an M2-brane with one of its internal directions wrapped around the compact dimensions. Anyway, these complexities aside, if we go right back to where we started, the key point is that quantum fields have particles, whose presence indicates a deviation from the ground state of the field, and the graviton is the particle of the metric field, indicating a deviation from flat space.
 
  • #5
some people think the the artificial split into a static background metric + quantized fluctuations on top of it cause severe problems for the whole program, and that no such background must be introduced
 
  • #6
tom.stoer said:
some people think the the artificial split into a static background metric + quantized fluctuations on top of it cause severe problems for the whole program, and that no such background must be introduced
As discovered long ago, this naïve perturbative approach to obtaining a quantum theory of gravity that reduces to General Relativity in the low-energy limit by simply quantizing the linearized gravitational field doesn`t work because General Relativity cannot be fully understood as just a theory of a self-interacting massless spin-2 field. There is only one known consistent perturbative approach to quantum gravity that does have the proper low-energy limit, and that`s string theory. In fact, at this point there is no nonperturbative approach (e.g., LQG etc) to quantum gravity that is known to achieve this.
 
  • #7
Harv said:
There is only one known consistent perturbative approach to quantum gravity that does have the proper low-energy limit, and that`s string theory.
The problem is that even with string theory you do not get fully dynamical quantized spacetime b/c spacetime (the classical background) is frozen in this approach. So even if perturbative string theory is consistent, it misses an essential feature of GR. Other non-perturbative and background independent approaches like LQG or AS seem to do a better job regarding fully dynamical spacetime and background independence, even if they fall short w.r.t. to the overall picture (but I know that I will never reach consensus here, neither with the loop nor with the string community)
 
  • #8
Even without going to Planck scale. I think the search for physics of wave functions of the metric is a separate thing, isn't it? Or how to quantize the metric.. this is not related to Planck scale, correct?
 
  • #9
stglyde said:
Even without going to Planck scale. I think the search for physics of wave functions of the metric is a separate thing, isn't it? Or how to quantize the metric.. this is not related to Planck scale, correct?

No. It is only near the Planck scale and above that it is uncertain what a consistent theory of quantum gravity is. See http://arxiv.org/abs/gr-qc/0108040 p17, the discussion starting from "Note that even though the perturbation theory described here does not provide an ultimate quantum theory of gravity, it can still provide a good effective theory for the low energy behavior of quantum gravity."
 
  • #10
There is a well developed theory called Quantum Field Theory in curved space-time. It treats the dynamics of "matter fields" on a background metric caused by massive bodies. Then, you can go ahead and calculate the stress-energy tensor due to these fields and use it in the Einstein's field equations.

In this respect, the "gravitational field" is treated classically, i.e. it develops according to Einstein's equations which minimize the action of the gravitational field. However, the sources of the gravitational field, namely, the stress-energy tensor of various particles is treated in a fully quantum fashion.

This partial theory predicts emission of particle-antiparticle pairs from the exterior of an event horizon of a black hole. The emitted spectrum looks just like a blackbody spectrum, with the temperature of the black hole being inversely proportional to its Schwarzschild radius (smaller black holes emit more). This causes evaporation of black holes.

It is interesting to notice that what was a static, or stationary, problem in General Relativity (we were solving for a metric that does not depend explicitly in time. As a necessary condition, the total mass-energy enclosed inside the Schwarzschild radius remains fixed, and the radius remains constant), has become an explicitly time-dependent problem, because as the black hole evaporates and looses energy, its radius shrinks.

To me, this is very similar to the failure of Classical Electrodynamics when applied to the atomic system, or simply by its own predictions. Namely, in the Rutherford model, the electron used to be in a dynamical balance because the attractive Coulomb force caused centripetal acceleration keeping it in a stable orbit around the nucleus. However, when we apply the laws of Classical Electrodynamics to the model, the accelerated electron, being a charged particle, should emit electromagnetic radiation, and spiral down to the nucleus in a very short time (of the order of 10-8 s). Nevertheless, this never happens. It took the genius of Niels Bohr to postulate that there are particular orbits on which the electron does not emit electromagnetic radiation. Thus, he essentially modified Classical Electrodynamics. The criterion by which these orbits were chosen was the quantization of the angular momentum of the electron around the nucleus, which also modified the laws of Classical Mechanics. Of course, it was later shown that the latter corresponds to so called semi-classical quantization conditions of the Quantum Mechanics. It took the development of Quantum Electrodynamics to resolve the mystery of the former prediction. QED also solves the absurdity of the prediction of classical electrodynamics that a charged particle should exponentially accelerate once it was accelerated in some external electric field due to its own radiation reaction force.

Up to now, there has been no conclusive evidence that Hawking radiation exists.
 
  • #11
atyy said:
No. It is only near the Planck scale and above that it is uncertain what a consistent theory of quantum gravity is.

Not necessarily. Quantum gravity effects are expected to be relevant at much larger distances than the Planck scale. Relatedly, non-perturbative, non-local/long-distance effects are likely to be relevant at the horizon of black holes, which can be very far away from the singularity at the origin.

See eg. here for a readable exposition: http://arXiv.org/pdf/1105.2036

Citation:

These notes have given sharpened statements that this unitarity crisis is a long-distance issue, and there is no clear path to its resolution in short-distance alterations of the theory...

While specific frameworks for quantum gravity have been proposed, they do not yet satisfactorily resolve these problems. Loop quantum gravity is still grappling with the problem of approximating flat space and producing an S-matrix. Despite initial promise, string theory has not yet advanced to the stage where it directly addresses the tension between the asymptotic and local approaches, or is able to compute a unitary S-matrix in the relevant strong gravity regime. Because of the long-distance and non-perturbative nature of the problem, it is also not clear how it would be addressed if other problems of quantum gravity were resolved, for example if supergravity indeed yields perturbatively finite amplitudes.
 
  • #12
atyy said:
No. It is only near the Planck scale and above that it is uncertain what a consistent theory of quantum gravity is. See http://arxiv.org/abs/gr-qc/0108040 p17, the discussion starting from "Note that even though the perturbation theory described here does not provide an ultimate quantum theory of gravity, it can still provide a good effective theory for the low energy behavior of quantum gravity."

Forgive me if this seems ignorant, but why should it be necessay to quantize the gravitational field? I mean aren't we really only interested in how the two fit together, where one comes from in terms of the other? I don't see that as necessarily requiring quantizing the gravitational field. Perhaps gravity is a emergent property. Or perhaps the metric is continuous, though curved, all the way down to the particle level. What phenomina or logic necessitates quantizing the gravitational field?
 
  • #13
friend said:
Forgive me if this seems ignorant, but why should it be necessay to quantize the gravitational field?
First reason: the Einstein equations read "metric-dependent terms = matter-dependent term"; b/c the r.h.s. is quantized, the l.h.s. should be quantized, too.
 
  • #14
tom.stoer said:
First reason: the Einstein equations read "metric-dependent terms = matter-dependent term"; b/c the r.h.s. is quantized, the l.h.s. should be quantized, too.

The quantization procesure of the matter-dependent term relies on a specific, continuous space-time background metric which is not quantized. This argues that there is no quantized gravity.
 
  • #15
friend said:
The quantization procesure of the matter-dependent term relies on a specific, continuous space-time background metric which is not quantized. This argues that there is no quantized gravity.
No, it means that quantization is incomplete. There MUST be quantized gravity, otherwise the equation is ill-definied.
 
  • #16
tom.stoer said:
No, it means that quantization is incomplete. There MUST be quantized gravity, otherwise the equation is ill-definied.

So, if the equation is modified there may be no need for quantization of gravity.
 
  • #17
martinbn said:
So, if the equation is modified there may be no need for quantization of gravity.
Einstein equations couple gravity to matter - and we know that matter is described by QFT. So how do you want to change the equation and couple gravity to non-quantized matter?
 
  • #18
atyy said:
No. It is only near the Planck scale and above that it is uncertain what a consistent theory of quantum gravity is. See http://arxiv.org/abs/gr-qc/0108040 p17, the discussion starting from "Note that even though the perturbation theory described here does not provide an ultimate quantum theory of gravity, it can still provide a good effective theory for the low energy behavior of quantum gravity."

I meant.. for low energy limit far from the Planck scale.. should the metric be quantized.. or should it only be quantized near the Planck scale, and why?
 
  • #19
As I said, we expect the geometry to be quantized for several reasons - mainly consistency reasons. Quantum effects would then be small far away from the Planck scale, i.e. quantum gravity would be the UV completion of an effective QFT on smooth classical spacetime (however there are proposals for so-called fuzzball black holes in string theory which indicate deviations from classical metric even far away from the Planck sale)
 
  • #20
Actually to be fair, there are some proposals out that challenge the conventional wisdom. One is classicalization and self-completeness. This posits that if one tries to probe the Planck scale, eg by an energetic scattering process, then one creates black holes before one ever enters into the quantum gravity regime. These are classical objects, so in this sense one never would be able to probe quantum gravity near the Planck scale: the theory protects itself. Pumping in more energy just makes the black holes larger and even more classical.

This is not undisputed, however, but some version of this may be true, perhaps only in particular kinematical regimes; see the ref. in my previous post. The key point is unitarity, not renormalizeability.

Nevertheless, for consistency, the whole theory needs to be quantum mechanical. This is independent of whether one can probe the Planck scale by scattering experiments or not.
 
  • #21
tom.stoer said:
Einstein equations couple gravity to matter - and we know that matter is described by QFT. So how do you want to change the equation and couple gravity to non-quantized matter?

I don't want that, just saying that may be the equation can be changed so that gravity need not be quantized. You, yourself, say that the equation has to be changed (the whole theory), but you use the equation (that has to be changed) as the reason why gravity should be quantized. I am only saying that that is not very convincing.
 
  • #22
I think you guys are running in circles with your discussion. Would you please define what you mean when you say an equation is "quantized", and similar terms. What is "classical" then?
 
  • #23
Dickfore said:
Would you please define what you mean when you say an equation is "quantized", and similar terms.

Where was that said?
 
  • #24
martinbn said:
Where was that said?

tom.stoer said:
First reason: the Einstein equations read "metric-dependent terms = matter-dependent term"; b/c the r.h.s. is quantized, the l.h.s. should be quantized, too.

Also, if you do a search of this thread for "quantized", you will see it is applied very liberally for various concepts. Could you define what you mean by "quantized" before you start discussing?
 
  • #25
First reason: the Einstein equations read "metric-dependent terms = matter-dependent term"; b/c the r.h.s. is quantized, the l.h.s. should be quantized, too.

Ah, but it does NOT say anything about an equation being quantized, right?

Dickfore said:
Also, if you do a search of this thread for "quantized", you will see it is applied very liberally for various concepts. Could you define what you mean by "quantized" before you start discussing?

I could.
 
  • #26
martinbn said:
Ah, but it does NOT say anything about an equation being quantized, right?
What does r.h.s or l.h.s. stand for?!

martinbn said:
I could.
Please do.
 
  • #27
There seems a lot of confusion. So let's do a little thought experiment. Just scatter two electrons - one from the left, the other coming from the right, in some rest frame.

Quantum mechanics is used to describe the scattering matrix. This is like a black box which tells you what comes out from this scattering process, given the incoming particles. And you want to have unitary scattering, so that probabilities do not exceed one. So far so good, I guess nobody objects that QM is the right concept here.

To make things easier, the electrons have an offset, or impact parameter, which is large, say 1km. Ordinarily one wouldn't expect that something would be peculiar or problematic.

But I didnt tell you that the kinetic energy of the electrons equals to the mass of a large star. A star with such a mass would form a black hole. So what's going to happen is that when the electrons are still, say 2km apart, a large black hole forms. But you don't really want to know the details now; all that matters is the "black box", or S-Matrix, and the question is, without caring about the details of what happens in the black box, what are the final states? Is the scattering unitary? This is obviously a quantum mechanical question. And if the scattering is unitary, this implies that the black hole must be able to decay. So Hawking radiation must necessarily occur, if quantum mechanics is supposed to be valid.

Note that this involves quantum mechanics and gravity, and ultra-plankian energies, but still these questions are insensitive to the Planck scale: small distances are not relevant here. So we talk about highly non-perturbative non-local effects.

Related problems occur when considering loops of virtual black holes; do these induce non-unitary scattering for low-energy particle physics? Better not!

Obviously one needs to describe gravity and quantum mechanics in one single coherent framework, in order to address this kind of questions. AFAIK a suitable framework to describe this quantitatively is still lacking. Although I know of some attempts using AdS/CFT.
 
  • #28
tom.stoer said:
As I said, we expect the geometry to be quantized for several reasons - mainly consistency reasons. Quantum effects would then be small far away from the Planck scale, ...

Planck scale this and Planck scale that... How can we be sure that any of the constants of nature and thus the Planck scale should remain the same as we approach ever more tightly curled up spacetimes? I mean, if we cannot see inside a black hole or cannot see the big bang, then it seems we are just guessing.
 
  • #29
suprised said:
There seems a lot of confusion. So let's do a little thought experiment. Just scatter two electrons - one from the left, the other coming from the right, in some rest frame.

Quantum mechanics is used to describe the scattering matrix. This is like a black box which tells you what comes out from this scattering process, given the incoming particles. And you want to have unitary scattering, so that probabilities do not exceed one. So far so good, I guess nobody objects that QM is the right concept here.

I see a big problem with this closed black box view - it is valid ONLY when the scattering picture is which is when you have an inert observer that can make observations as well as preparations from a distance where the coupling to the black box is is weak/controlled in the sense that the observer itself (which is a generalized "background") does not severly deform during the interaction.

The other problem is that it also only makes sense when ensembles can be realized.

In cosmological pictures, where the observer is strongly coupled, the observers entire ENVIRONMENT (ie remainder of the universe) is the effective "black box", and here most of the premises in the scattering picture fails. Also an inside observer can hardly encode arbitrary amounts of inforamtion - something that is usually not cared about in a good way in the scattering pictures as I see it.

It's no news that my own view is that QM formalism as it stands is unlikely to be sufficient here. That's not to say the scattering matrix is interesting, it is. But I think it's a good abstraction of observed reality only in limiting/special case.

/Fredrik
 
  • #30
Fra said:
In cosmological pictures, where the observer is strongly coupled, the observers entire ENVIRONMENT (ie remainder of the universe) is the effective "black box", and here most of the premises in the scattering picture fails. Also an inside observer can hardly encode arbitrary amounts of inforamtion - something that is usually not cared about in a good way in the scattering pictures as I see it.

It's no news that my own view is that QM formalism as it stands is unlikely to be sufficient here. That's not to say the scattering matrix is interesting, it is. But I think it's a good abstraction of observed reality only in limiting/special case.

Well I am not talking about cosmological pictures, but just a transplanckian scattering experiment, if you wish with asymptotic oberservers. So what is the S-Matrix for this scattering? It should have a concrete answer, and better be unitary.

If you dispute the valitidy of QM and the S-Matrix - well QM has been proven to be extremely robust against deformations and so far no one, AFIAK, was able to replace it by something else. It is very common (because cheap) to say "according to my opinion QM needs somehow be modified", but very difficult to actually do it ...
 
  • #31
Dickfore said:
I think you guys are running in circles with your discussion. Would you please define what you mean when you say an equation is "quantized", and similar terms. What is "classical" then?

Why circles? This just means it's an equation involving operators. And this makes sense only if the complete equation, and not just part of it, becomes operator valued.
 
  • #32
suprised said:
Why circles? This just means it's an equation involving operators. And this makes sense only if the complete equation, and not just part of it, becomes operator valued.

:uhh:

So, what is the meaning of the operators [itex]g_{\mu \nu}[/itex], and [itex]R_{\mu \nu}[/itex]?
 
  • #33
Dickfore said:
:uhh:

So, what is the meaning of the operators [itex]g_{\mu \nu}[/itex], and [itex]R_{\mu \nu}[/itex]?

It turns them into probability distributions instead of absolute values.
 
  • #34
friend said:
It turns them into probability distributions instead of absolute values.

Please elaborate. Are you saying the metric tensor becomes a probability distribution? If yes, whose random variable it is a distribution of? Or, is the metric tensor a (multivariate) random variable. In this case, what determines its distribution?
 
  • #35
In canonically quantized GR g and R are field operators with a huge gauge symmetry and therefore w/o a direct physical meaning.
 
<h2>1. What is the relationship between quantum field theory and general relativity?</h2><p>Quantum field theory (QFT) and general relativity (GR) are two of the most successful theories in physics, but they describe very different phenomena. QFT explains the behavior of particles at the microscopic level, while GR describes the behavior of gravity at the macroscopic level. However, they are both fundamental theories that aim to describe the fundamental laws of nature, and there have been attempts to combine them into a single theory known as quantum gravity.</p><h2>2. How does QFT with respect to general relativity differ from traditional QFT?</h2><p>Traditional QFT is based on the principles of special relativity, which describes the behavior of particles in flat spacetime. In QFT with respect to general relativity, the principles of general relativity are taken into account, which describes the curvature of spacetime due to the presence of mass and energy. This means that QFT with respect to general relativity can better describe phenomena that involve both quantum mechanics and gravity, such as black holes.</p><h2>3. What are the challenges in combining QFT with general relativity?</h2><p>One of the main challenges in combining QFT with general relativity is that they use different mathematical frameworks. QFT uses the principles of quantum mechanics, which are described by the mathematical framework of Hilbert spaces and operators. On the other hand, general relativity uses the principles of classical mechanics, which are described by the mathematical framework of differential geometry. Finding a way to reconcile these two frameworks has been a major challenge in the field of quantum gravity.</p><h2>4. What are some proposed theories that attempt to combine QFT with general relativity?</h2><p>There are several proposed theories that attempt to combine QFT with general relativity, such as string theory, loop quantum gravity, and causal dynamical triangulations. These theories all have different approaches to reconciling the principles of quantum mechanics and general relativity, and they are still being actively researched and developed.</p><h2>5. How does QFT with respect to general relativity impact our understanding of the universe?</h2><p>QFT with respect to general relativity has the potential to greatly impact our understanding of the universe by providing a more complete and unified theory of the fundamental laws of nature. It may also help to solve some of the biggest mysteries in physics, such as the nature of dark matter and dark energy, and the origin of the universe. However, this field is still in its early stages and more research and experimentation is needed to fully understand its implications.</p>

1. What is the relationship between quantum field theory and general relativity?

Quantum field theory (QFT) and general relativity (GR) are two of the most successful theories in physics, but they describe very different phenomena. QFT explains the behavior of particles at the microscopic level, while GR describes the behavior of gravity at the macroscopic level. However, they are both fundamental theories that aim to describe the fundamental laws of nature, and there have been attempts to combine them into a single theory known as quantum gravity.

2. How does QFT with respect to general relativity differ from traditional QFT?

Traditional QFT is based on the principles of special relativity, which describes the behavior of particles in flat spacetime. In QFT with respect to general relativity, the principles of general relativity are taken into account, which describes the curvature of spacetime due to the presence of mass and energy. This means that QFT with respect to general relativity can better describe phenomena that involve both quantum mechanics and gravity, such as black holes.

3. What are the challenges in combining QFT with general relativity?

One of the main challenges in combining QFT with general relativity is that they use different mathematical frameworks. QFT uses the principles of quantum mechanics, which are described by the mathematical framework of Hilbert spaces and operators. On the other hand, general relativity uses the principles of classical mechanics, which are described by the mathematical framework of differential geometry. Finding a way to reconcile these two frameworks has been a major challenge in the field of quantum gravity.

4. What are some proposed theories that attempt to combine QFT with general relativity?

There are several proposed theories that attempt to combine QFT with general relativity, such as string theory, loop quantum gravity, and causal dynamical triangulations. These theories all have different approaches to reconciling the principles of quantum mechanics and general relativity, and they are still being actively researched and developed.

5. How does QFT with respect to general relativity impact our understanding of the universe?

QFT with respect to general relativity has the potential to greatly impact our understanding of the universe by providing a more complete and unified theory of the fundamental laws of nature. It may also help to solve some of the biggest mysteries in physics, such as the nature of dark matter and dark energy, and the origin of the universe. However, this field is still in its early stages and more research and experimentation is needed to fully understand its implications.

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