Light-dragging effects

Light-dragging effects

In physics, there are several situations in which the motion of matter might be said to "drag light".

Under special relativity's simplified model it is assumed that these light-dragging effects do not happen, and that the speed of light is independent of the speed of a body's motion. However, the special theory of relativity does not claim to deal with "particulate matter" effects or gravitational effects, or to provide a complete relativistic description of acceleration effects — when more realistic assumptions are made (real objects are made of particulate matter, and/or have gravitational properties), the resulting descriptions include light-dragging as an effect.

Velocity-dependent effects

* For a moving particulate body, light moving through the body's structure is known to move faster in the direction of the body's motion than it does in the opposite direction (Fizeau experiment). This effect was originally predicted by dragged-aether theories ("see::, e.g. Fresnel"). Light aimed transversely through a moving transparent body is also seen to be deflected in the direction of the body's motion (R.V. Jones, J.Phys A 4 L1-L3 (1971) ).

* For a moving gravity-source the gravitational field can be considered as an extension of the object, and carries inertia and momentum - since a direct collision with the moving object can impart momentum to an external particle, interaction with the object's gravitational field should allow "momentum exchange", too. Consequently, a moving gravitational field drags light and matter. This general effect is used by NASA to accelerate space probes, using the gravitational slingshot effect.

* In the case of rotation under general relativity (see below), we also have an apparent velocity-dependent dragging effect, since for a rotating body, the tendency of the object to pull things around with it can be described by saying that the receding part of the object pulls more strongly than the approaching part.

Acceleration-dependent effects

Under general relativity, the acceleration of a body in a straight line drags light. See frame-dragging

Rotation-dragging effects

Under general relativity, the rotation of a body gives it an additional gravitational attraction due to its kinetic energy, and light is also pulled around (to some degree) by the rotation (Lense-Thirring effect).

References

* R.W. Ditchburn, Light, (3rd ed.), Vol.2 (Academic Press, London, 1976) "- light and the motion of particulate media"

* Kip Thorne, Black holes and timewarps: Einstein's outrageous legacy (Norton, NY, 1995) "- frame-dragging around black holes"

ee also

* Aether drag
* Democratic principle


Wikimedia Foundation. 2010.

Игры ⚽ Нужно сделать НИР?

Look at other dictionaries:

  • Frame-dragging — Albert Einstein s theory of general relativity predicts that rotating bodies drag spacetime around themselves in a phenomenon referred to as frame dragging. The rotational frame dragging effect was first derived from the theory of general… …   Wikipedia

  • Coriolis field — In theoretical physics a Coriolis field is one the apparent gravitational fields felt by a rotating or forcibly accelerated body, together with the centrifugal field and the Euler field. Contents 1 Mathematical expression 2 Mach s view 2.1 Is it… …   Wikipedia

  • Pieter Zeeman — Infobox Scientist name = Pieter Zeeman imagesize = 180px caption = Pieter Zeeman birth date = birth date|1865|5|25|mf=y birth place = Zonnemaire, Netherlands death date = death date and age|1943|10|9|1865|5|25 death place = Amsterdam, Netherlands …   Wikipedia

  • General relativity — For a generally accessible and less technical introduction to the topic, see Introduction to general relativity. General relativity Introduction Mathematical formulation Resources …   Wikipedia

  • Timeline of luminiferous aether — The timeline of luminiferous aether begins in the late 19th century with the concept of luminiferous aether ( light bearing aether ), or ether, as a medium for electromagnetic propagation. The aether was assumed to exist for much of the 19th… …   Wikipedia

  • Route-dependence — In theoretical physics, the issue of route dependence deals with whether a selected differential between two points is taken as , or as being partly a function of the route along which comparative measurements are taken. It usually applies in… …   Wikipedia

  • Polarizable vacuum — In theoretical physics, particularly fringe physics, polarizable vacuum (PV) most often refers to a proposal by Harold Puthoff to develop an analogue of general relativity to describe gravity in optics like terms. Puthoff himself has apparently… …   Wikipedia

  • Emission theory — (also called emitter theory ) was a competing theory for the special theory of relativity, explaining the results of the Michelson Morley experiment. Emission theories obey the principle of relativity by having no preferred frame for light… …   Wikipedia

  • De Sitter double star experiment — This article is about observing binary stars. For precession of orbiting bodies, see de Sitter precession. de Sitter s double star argument The de Sitter effect was described by de Sitter in 1913 and used to support the special theory of… …   Wikipedia

  • Ring singularity — In general relativity the gravitational singularity at the center of a rotating black hole (a Kerr black hole ) is supposed to form a circle rather than a point. This is often referred to as a ring singularity.Description of a ring… …   Wikipedia

Share the article and excerpts

Direct link
Do a right-click on the link above
and select “Copy Link”