Difference between acceleration and gravitational field?

In summary: Well the equivalence principle is also only valid for a given distance scale. If you look at a large enough distance scale you can observe geodesic deviation and can conclude that you are in a gravitational field and not simply accelerating.In summary, the equivalence principle says that you can't tell the difference between being accelerated in an elevator, or being in a gravitational field. However, there are possible ways to detect gravitons, and they may be involved in the exchange of mass and energy.
  • #1
curtdbz
24
0
This is something I've always wondered... Einstein's equivalence principle says that you can't tell the difference between being accelerated in an elevator, or being in a gravitational field. No matter what, there's no mechanical device you can build, etc.

But, what about 'gravitons'? Aren't those supposed to be mediators for the gravity force (if they exist)? Can you tell by observing them that you're in a g-field and not an elevator that's accelerating?
 
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  • #2
I don't think the answer to your question is known, since we don't have a theory of quantum gravity. A theory of quantum gravity may have to throw out certain cherished principles of GR and QM, but we don't know which ones. If one of the principles to be abandoned is the equivalence principle, then the answer to your question would be yes. There are strong reasons to believe that gravitons can never be physically detected: http://arxiv.org/abs/gr-qc/0601043
 
  • #3
It is also possible that in an accelerated frame in empty space the graviton detector will detect gravitons. Some effect similar to Unruh effect.
 
  • #4
martinbn said:
It is also possible that in an accelerated frame in empty space the graviton detector will detect gravitons. Some effect similar to Unruh effect.

That sounds plausible. Maybe somebody can try accelerating the detector in bcrowell's reference to see if the cross-section increases :wink:
 
  • #5
martinbn said:
It is also possible that in an accelerated frame in empty space the graviton detector will detect gravitons. Some effect similar to Unruh effect.

This is sensible. There are pretty general arguments that the number of quanta is observer-dependent when you interface GR to quantum fields. (I think this is discussed in the appendix in Wald on quantum stuff, and also in Carroll.) The same would presumably apply when the quantum field is gravity itself.
 
  • #6
That's an interesting point.
We'd have to detect and understand gravitons a little better, of course.

I personally believe, though, that the act of acceleration would require exchanges of gravitons in order to facilitate the exchanges of mass/energy.
 
  • #7
Well the equivalence principle is also only valid for a given distance scale. If you look at a large enough distance scale you can observe geodesic deviation and can conclude that you are in a gravitational field and not simply accelerating.
 

What is acceleration?

Acceleration is the rate at which an object changes its velocity. It is a vector quantity that includes both magnitude and direction. In simpler terms, it is how quickly an object's speed or direction changes.

What is gravitational field?

Gravitational field is a region in space where a mass experiences a force due to the presence of another mass. It is a vector field that points towards the direction of the force and its strength is determined by the masses of the objects and the distance between them.

How are acceleration and gravitational field related?

Acceleration and gravitational field are related in that acceleration due to gravity is a specific type of acceleration caused by the gravitational field of a massive object. The acceleration due to gravity is the same for all objects within a given gravitational field, regardless of their mass.

What is the difference between acceleration and gravitational field?

The main difference between acceleration and gravitational field is that acceleration is a measure of how quickly an object's velocity changes, while gravitational field is a measure of the force that causes this acceleration. Acceleration is a vector quantity, while gravitational field is a vector field. Additionally, acceleration can be caused by sources other than gravity, while gravitational field is specific to gravity.

Can acceleration and gravitational field be negative?

Yes, both acceleration and gravitational field can be negative. A negative acceleration indicates a decrease in velocity, while a negative gravitational field can indicate a repulsive force between two objects, such as in the case of two like charges in electromagnetism.

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