Is Gravity Faster Than Light in Black Holes?

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Discussion Overview

The discussion centers around the nature of gravity in the context of black holes, specifically whether gravity can exceed the speed of light and how this relates to the behavior of gravitational forces and the concept of gravitons. Participants explore theoretical implications, the compatibility of general relativity (GR) with observations, and the role of dark matter in explaining galactic rotation curves.

Discussion Character

  • Debate/contested
  • Technical explanation
  • Conceptual clarification

Main Points Raised

  • Some participants propose that if gravity is mediated by gravitons traveling at the speed of light, then gravity itself must exceed this speed to escape a black hole.
  • Others argue that in standard GR, nothing can escape a black hole, and the gravitational field is determined by the mass and angular momentum of the object, remaining unchanged after the object has fallen into the black hole.
  • One participant suggests that GR fails to explain the galactic rotation curves, which leads to discussions about alternatives like dark matter or modifications to GR.
  • There are claims that the existence of gravitons would imply they must travel faster than light, which raises questions about the compatibility of quantum physics with GR.
  • Some participants express skepticism about the concept of gravitons, suggesting that gravity does not operate like electromagnetic forces and should not be treated as mediated by particles.
  • Multiple participants note that the effects of gravity propagate at the speed of light, contradicting the notion that gravitons could travel faster than light.

Areas of Agreement / Disagreement

Participants express a range of views, with no consensus on whether gravity can exceed the speed of light or how to reconcile GR with observations of galactic rotation curves. The discussion remains unresolved with competing theories and interpretations presented.

Contextual Notes

Participants highlight limitations in GR's applicability on galactic scales and the challenges in reconciling quantum theories of gravity with established relativistic frameworks. There are unresolved questions regarding the nature of gravitational interactions and the implications of potential faster-than-light influences.

Eric R. Blacker
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If a black hole has a radius past which light cannot escape. How does the gravity get out?

If the force carrier of gravity, the graviton, travels at the speed of light it too would be trapped.

Assuming there are black holes and they are gravitating bodies, then the force carrier of gravity must exceed the speed of light.

Is this possible? Expansion faster than light is already part of Guth's early inflationary model.

Two opposing views might be that gravity is faster than light or that space-time once curved by a gravitating body remains curved even after the body has disappeared into a black hole.

Which of these ideas fits the galactic rotation velocity curve better?
 
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In standard GR, nothing "gets out" of a black hole or exceeds the speed of light. The gravitational field is determined by the shape of space-time. The field at a given distance from a black hole is determined at the time something falls past that point, and remains unchanged afterwards. The field at a distance from an object is only determined by the mass and angular momentum of the object, and not by whether it is a black hole.

In other words, this is the option which is correct (except that it should be "space-time" rather than space"):

"Space once curved by a gravitating body remains curved even after the body has disappeared into a black hole."

Gravitons are effectively an alternative QM way of looking at gravity, instead of general relativity, and at present I am not aware of any consistent relativistic theory of gravitons, so it is difficult to say anything about them.

GR does predict gravitational waves, which relate to rapid changes in the field, and propagate at the local speed of light.

Experiments are consistent with gravitational changes propagating at the speed of light, as predicted by GR, and with other very accurate predictions of GR in regions dominated by single central massive sources, such as in the solar system.

Any idea involving some form of influence propagating faster than light is not compatible with special relativity and causality; it implies that either there are preferred frames or that causality can be violated. (However, any deterministic form of QM requires such an influence).

GR on its own (without dark matter and dark energy) does not appear to be consistent with cosmological observations either on the galactic scale or higher. I'm not personally sure that dark anything is the correct fix; I think it more likely that GR isn't right on larger scales.
 
Jonathan,

Thank you for your response.

How does GR fail to fit the galactic rotation curve data?
 
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The bottom line, IMO, is that gravity is not intermediated by an EM like 'particle'. Or in other words, Einstein was right.
 
Eric R. Blacker said:
Jonathan,

Thank you for your response.

How does GR fail to fit the galactic rotation curve data?

On galactic scales, GR basically reduces to Newtonian theory plus some minor relativistic considerations. However, it is well-known that Newtonian theory based on the visible distribution of luminous objects does not explain the rotation curves for most galaxies.

I'm sure you should be able to find plenty about that by searching the web, for example looking up "galaxy rotation curve" in Wikipedia, which looks like a reasonable starting point.

The main alternatives seem to be "dark matter" or some change to GR, as in the empirical MOND model or Moffat's MOG. There have also been attempts to investigate the possibility that the geometrical distribution of stars in structures such as spiral arms may give rise to additional forces which are not being taken into account in the models which assume a more uniform mass distribution. However, I don't think any of these ideas have been particularly successful.
 
Well, I know NOTHING about this stuff, but if a gravition was supposedly the force carrying particle of gravity (which we have no real proof for as of yet) then it IS gravity. It's not affected by gravity. It would be fundamentally different from a photon or something, and would not be sucked back in by it's own gravity. You can't have the space-time trampoline analogy and also have the particle billiard ball analogy. You're having your cake and eating it too!
 
nhmllr said:
a gravition was supposedly the force carrying particle of gravity (which we have no real proof for as of yet) then it IS gravity. It's not affected by gravity.

That is not correct.

nhmllr said:
Well, I know NOTHING about this stuff

IF so, that's probably a good reason to ask questions rather than make pronouncements. In ay event, this thread is 2 years old.
 
To consider the existence of gravitons, as in quantum physics, is to completely disregard General relativity (im not saying GR is perfect but..). We know objects react instantly (or very fast anyway) to gravity and that to have gravitons means that they must travel faster than light.
So why are quantum physicists theorising and looking for gravitons. Or do they acknowlege that, if they exist, they must be faster than light? Yeah its an old topic .. I couldn't find a more relevant section.
 
mammalian said:
To consider the existence of gravitons, as in quantum physics, is to completely disregard General relativity (im not saying GR is perfect but..). We know objects react instantly (or very fast anyway) to gravity and that to have gravitons means that they must travel faster than light.
So why are quantum physicists theorising and looking for gravitons. Or do they acknowlege that, if they exist, they must be faster than light? Yeah its an old topic .. I couldn't find a more relevant section.

Actually, the effect of gravity travels at exactly light speed, so in theory a graviton would have to too.
 
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mammalian said:
To consider the existence of gravitons, as in quantum physics, is to completely disregard General relativity (im not saying GR is perfect but..). We know objects react instantly (or very fast anyway) to gravity and that to have gravitons means that they must travel faster than light.
So why are quantum physicists theorising and looking for gravitons. Or do they acknowlege that, if they exist, they must be faster than light? Yeah its an old topic .. I couldn't find a more relevant section.

GR actually predicts that the effects of gravity travel at the speed of light. Gravitons would allow us to bring gravity into the fold along with the other forces, so it is an appealing notion to science.
 

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