Travelling faster than the speed of light?

Aero_Marty
Messages
11
Reaction score
0
Hey everyone,

Im new to this forum, was not sure whether or not to post this question here...

I heard about an experiment where a beam of light was aparently teleported a short distance, I am unsure as to how this is possible, but my question is regarding the speed that beam is travelling.

If it is instantaneously teleported a distance then according to simple laws of motion v=d/t, then the velocity would prove to be faster than the speed of light, but aparently it is impossible to travel faster than the speed of light. How can this be explained? Is there another theory I am unaware of?

Marty
 
Physics news on Phys.org
The "teleported" photon doesn't actually travel to the destination. What happens is that its polarization state is transferred to another photon. The process changes the polarization state of the original photon, so the polarization state isn't being copied. It's transferred. The reason why this can be called "teleportation" at all is that photons are indistinguishable, so the end result is the same as if the original photon had actually moved to the the destination, while another photon was moved from the destination to the starting point (probably with a changed polarization state...not sure about that).

The "transfer" isn't instantaneous, because after you have performed a measurement at the site where the original photon is, you actually have to send some information to the destination site by some other means (pigeons? :smile:), so that the experimenter at that site knows what interaction he's supposed to subject his photon to, in order to reproduce the original photon's polarization state.

I probably gave you the impression that what I'm describing is "measure the polarization of the photon at A, and than give the photon at B the state that's the result of that measurement". That's not what happens. A measurement of the polarization of the original photon would change its polarization state, so we'd end up giving the photon at B the wrong state. We want the photon at B to end up in the state that the photon at A was in before we did anything to it, so the measurement performed at A needs to be something more clever than just a measurement of the polarization of the photon that we want to "teleport".
 
Haha... pigeons, awesome.

Ah I see, so nothing is actually transported at all.

If I'm getting this right, then the analogy to teleporting a human say, would be that an exact copy of their physical form at that current point in time would have to be given to an existing "blank" body at another location (obviously considering this possibility hypothetically). Their consciousness would then have to be somehow uploaded, transported and then downloaded again into the other body.

I know this is a bit 'out there' but its something I've been wondering about. Basically, even if all the technology was around for this to happen, teleportation as I would think of it (instantaneous transportation) is not possible?

Thanks for your reply, I was unsure of the details of that experiment.

Cheers, Marty
 

Thread 'I don't see how a black hole's event horizon can be crossed'

OK, so this has bugged me for a while about the equivalence principle and the black hole information paradox. If black holes "evaporate" via Hawking radiation, then they cannot exist forever. So, from my external perspective, watching the person fall in, they slow down, freeze, and redshift to "nothing," but never cross the event horizon. Does the equivalence principle say my perspective is valid? If it does, is it possible that that person really never crossed the event horizon? The...
View full post »

Thread 'Is the variation of the metric ##\delta g_{\mu\nu}## a tensor?'

From $$0 = \delta(g^{\alpha\mu}g_{\mu\nu}) = g^{\alpha\mu} \delta g_{\mu\nu} + g_{\mu\nu} \delta g^{\alpha\mu}$$ we have $$g^{\alpha\mu} \delta g_{\mu\nu} = -g_{\mu\nu} \delta g^{\alpha\mu} \,\, . $$ Multiply both sides by ##g_{\alpha\beta}## to get $$\delta g_{\beta\nu} = -g_{\alpha\beta} g_{\mu\nu} \delta g^{\alpha\mu} \qquad(*)$$ (This is Dirac's eq. (26.9) in "GTR".) On the other hand, the variation ##\delta g^{\alpha\mu} = \bar{g}^{\alpha\mu} - g^{\alpha\mu}## should be a tensor...
View full post »

Thread 'Synchronizing clocks in an inertial frame if light is anisotropic'

ASSUMPTIONS 1. Two identical clocks A and B in the same inertial frame are stationary relative to each other a fixed distance L apart. Time passes at the same rate for both. 2. Both clocks are able to send/receive light signals and to write/read the send/receive times into signals. 3. The speed of light is anisotropic. METHOD 1. At time t[A1] and time t[B1], clock A sends a light signal to clock B. The clock B time is unknown to A. 2. Clock B receives the signal from A at time t[B2] and...
View full post »

Similar threads

B Let me ask a thing about the Speed of Light
Replies
6
Views
2K
B Time Travel: Can Humans Go Faster Than Ordinary Speed?
Replies
9
Views
2K
I A question about the speed of light and electromagnetism
2
Replies
51
Views
4K
I Light Speed in Dense Medium: Explained
Replies
1
Views
2K
B Would We See the Same Light After Traveling Back to Earth Faster Than Light?
Replies
2
Views
2K
B Can Curved Spacetime Enable Faster-Than-Light Travel?
Replies
12
Views
3K
A Speed of Light for Bonnor Beam
Replies
26
Views
1K
I Can Propeller Speeds and Wave Breaks Challenge the Speed of Light?
Replies
13
Views
1K
B Why is it impossible to go faster than the speed of light?
Replies
21
Views
3K
I Time & Gravity in Rotating Faster Than Light?
Replies
8
Views
2K

Hot Threads

Recent Insights

Back
Top