At what point does gravity become incompatible with QM?

In summary, the conversation discusses the idea of quantum mechanics and general relativity being incompatible and the possibility of quantum mechanics failing at larger distances and for larger objects. However, a perfectly valid quantum theory of gravity exists, it just needs to include a cutoff at the Planck scale. This means that the issue of quantum gravity is not a fundamental incompatibility, but rather the need for a more complete theory beyond the range of their combined applicability.
  • #1
Cody Richeson
60
2
Is there some fuzzy area between the macroscopic and atomic worlds where gravity "still sort of works," or is it a dramatic cut off? I never understood this whole idea that it suddenly stops making sense at the quantum level. Does it start making progressively more sense as you increase the scale?
 
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  • #2
Gravity doesn't just stop making sense at the quantum mechanical level. We have no problem treating gravity quantum mechanically below energies of 10^19 GeV or so. (This is 10^15 times higher than the energy scale reached by the LHC). Above that point, the math tells us that the simplest quantum mechanical version of general relativity stops being valid, so something new must take over--perhaps string theory. Note that string theory is itself a quantum mechanical theory.
 
  • #3
The problem with gravity is not so much that it doesn't make sense, but that it just doesn't need to be treated quantum mechanically: It is (1) very very weak compared to other forces in the systems and (2) doesn't change much at microscopic scales. In most microscopic processes, pretending gravity doesn't exist is an effectively exact approximation, and if it is not, then treating it at the level of F = m*g certainly is. (That's not even taking into account the effects at classical mechanics level...)
 
  • #4
Check out:
http://arxiv.org/pdf/gr-qc/9512024v1.pdf
http://arxiv.org/pdf/1209.3511v1.pdf

'One can find thousands of statements in the literature to the effect that “general relativity and quantum mechanics are incompatible”. These are completely outdated and no longer relevant. Effective field theory shows that general relativity and quantum mechanics work together perfectly normally over a range of scales and curvatures, including those relevant for the world that we see around us. However, effective field theories are only valid over some range of scales. General relativity certainly does have problematic issues at extreme scales. There are important problems which the effective field theory does not solve because they are beyond its range of validity. However, this means that the issue of quantum gravity is not what we thought it to be. Rather than a fundamental incompatibility of quantum mechanics and gravity, we are in the more familiar situation of needing a more complete theory beyond the range of their combined applicability. The usual marriage of general relativity and quantum mechanics is fine at ordinary energies, but we now seek to uncover the modifications that must be present in more extreme conditions. This is the modern view of the problem of quantum gravity, and it represents progress over the outdated view of the past.'

The short answer is about the plank scale.

The longer answer is gravity is not incompatible with QM - a perfectly valid quantum theory of gravity exists - it is just not renormalisable, which means a cutoff must be explicitly included, and the cutoff is about the plank scale. The difference between renormalisable and non-renormalisable theories is renormalisable theories have a magical property - what we observe does not depend on the cut-off. We know, QED for example, breaks down well before the plank scale so it really has a cutoff as well but it doesn't need to be explicitly included in the theory because of the magic property it has of renormalisability - the precise value of that cutoff doesn't matter. But the jig is up with gravity.

Thanks
Bill
 
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  • #6
audioloop said:
...However, as Richard Feynman once said, "Quantum theory does not absolutely guarantee that gravity has to be quantized. ... I would like to suggest that it is possible that quantum mechanics fails at large distances and for larger objects." ...

Quantum theory does not absolutely guarantee anything has to be quantized. However given a field Lagrangian the fact you can is very telling and allows theories to be developed and predictions made, which is what science is all about.

Feynman may be right, he may be wrong - exactly as it is with all speculation. What we need is a well developed alternate theory that makes predictions that can be tested. And that was pretty much Feynman all over - correspondence with experiment is his bottom line.

Thanks
Bill
 
  • #7
bhobba said:
Quantum theory does not a[STRIKE]bsolutely[/STRIKE] guarantee anything has to be quantized.
Bill



Righttttttt !
 
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  • #8

Related to At what point does gravity become incompatible with QM?

1. What is the current understanding of the relationship between gravity and quantum mechanics?

At present, the most widely accepted theory for the relationship between gravity and quantum mechanics is the theory of general relativity, which describes gravity as the curvature of spacetime caused by the presence of massive objects. However, this theory is incompatible with the principles of quantum mechanics, which govern the behavior of particles on a subatomic level.

2. What is the concept of "quantum gravity"?

"Quantum gravity" refers to the theoretical framework that attempts to reconcile the principles of quantum mechanics with those of general relativity. It is believed that a theory of quantum gravity would provide a more complete understanding of the fundamental forces and particles in the universe.

3. How do scientists currently approach the study of gravity and quantum mechanics?

Scientists are currently exploring various theories and models in an attempt to bridge the gap between gravity and quantum mechanics. This includes approaches such as string theory, loop quantum gravity, and other quantum gravity models.

4. Why is it difficult to unify gravity and quantum mechanics?

The main challenge in unifying gravity and quantum mechanics lies in the fundamental differences between the two theories. Gravity is a classical theory that describes the behavior of large-scale objects, while quantum mechanics is a quantum theory that describes the behavior of particles on a small scale. These two theories have different mathematical frameworks and principles, making it difficult to reconcile them.

5. What are the potential implications of a successful theory of quantum gravity?

A successful theory of quantum gravity would have significant implications for our understanding of the universe and could potentially lead to breakthroughs in areas such as cosmology, particle physics, and even technology. It could also help explain some of the most perplexing phenomena in the universe, such as black holes and the origins of the universe.

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