ORF said:Does the spacetime curvature produced by an object affect the object itself?
The principle equivalence is exact only in various limits. The source WBN cites quantifies the degree to which bodies deviate from exact geodesic motion due to self gravity.Mueiz said:No..The spacetime curvature pruduced by an object cannot affect the object itself ..What is mentioned in the answer above correct but this related to the effects of
different parts of a body on other part ..but a single object can not affected by itself .this can by understood directly from the Principle of Equivalence because the motion of an object in gravitational field does not affected by the mass of the body and thus the curvature produced by it.
ORF said:Hello
Does the spacetime curvature produced by an object affect the object itself?
Thank you in advance :)
Greetings!
1977ub said:An extended object would consist of an ensemble of interacting particles. Presumably part of this interaction would consist of spacetime distortions aka "gravitational forces" ?
1977ub said:No, but spacetime curvature produced by part of an object can affect another part.
How does GR handle point-masses? My understanding is that the full non-linear theory can't do it in principle, one has to use idealized test particles without bacreaction.WannabeNewton said:The space-time curvature of a point-particle does back-react on the particle; here there are no internal degrees of freedom so your answer would not hold. The same thing happens in EM for a point charge so this isn't special to GR. It's just more complicated in the latter case.
WannabeNewton said:The space-time curvature of a point-particle does back-react on the particle; here there are no internal degrees of freedom so your answer would not hold. The same thing happens in EM for a point charge so this isn't special to GR. It's just more complicated in the latter case.
Spacetime curvature is the idea that the fabric of space and time is not flat and can be bent by the presence of massive objects, such as planets or stars.
Spacetime curvature affects objects by causing them to follow curved paths in the presence of massive objects. This can be seen in the way that planets orbit around stars, as their paths are affected by the curvature of spacetime caused by the star's mass.
Yes, spacetime curvature can be observed through the effects it has on objects. For example, the bending of light around massive objects, known as gravitational lensing, is a result of spacetime curvature.
Einstein's theory of general relativity explains the concept of spacetime curvature and how it is caused by the presence of mass and energy. It is considered one of the most accurate theories for understanding the behavior of gravity.
Yes, spacetime curvature can be measured through various methods, such as the use of gravitational lensing, the observation of the motion of planets and stars, and the detection of gravitational waves. These measurements provide evidence for the existence and effects of spacetime curvature.