RandallB said:
Come on Vanesch help this guy out, he’s digging himself into hole.
Well, I'm sorry but I'm rather in agreement with what JesseM writes, only, it seems that you guys are talking next to each other. That said, I am also in agreement with certain points you make ; however, both are not contradictory.
There are two totally different issues here, which I hoped I was making clear. There is one point, which is: "making interference patterns" of beams of a certain quality. And then there is another point, and that is: doing measurements in such a way that the entangled quality of two beams is used (and eventually, how this plays out in trying to make FTL signaling devices).
The confusing issue here is the term "making interference patterns", which can mean different things. Clearly, an ideal, monochromatic, linearly polarized beam of light will ALWAYS make an interference pattern in a 2-slit experiment ; also, such a beam can NEVER be the "one arm" of an entangled set of beams!
In quantum speak, if our beam is "in a pure state", then it factors out in the overall wavefunction, and hence, by definition, is not entangled.
Now, in order to have interference, it is not necessary to have a pure state. You can also have interference in mixtures, but not always: only when the two components that are to interfere are sufficiently correlated. This is what is classically described by coherence lengths and times. This is why even "noisy" light can give interference patterns, if only we work with small enough coherence lengths and times. But once we go beyond these small coherence lengths and times, there is no interference anymore.
So a statistical mixture of pure states will give rise to a limited capability to give rise to interference.
Now, what with entanglement ? The whole point by using interference in entangled states is to try to have "one slit" of beam A to correspond with a measurable property of beam B, and "the other slit" of beam A to correspond with the complementary property of beam B. This is interesting because it gives us the idea that we might "cheat" on the interference mechanism: by using the measureable property on beam B, we might find out (potentially) through which slit beam A went, and nevertheless have an interference pattern. THIS is what is impossible, for the following reason.
AS LONG AS IT IS POTENTIALLY POSSIBLE (I'm with JesseM here) to do so, no interference pattern can be obtained by beam A.
But this is not due to some magic "weird behaviour of beam A", rather, it is because beam A, when looked at locally, will correspond exactly to such a statistical mixture, that the desired interference experiment will lie outside of the coherence lengths and times that are necessary for obtaining an interference pattern in these conditions.
Now, somebody who only has access to beam A, would be totally in agreement with this find, because he would, after doing some spectral analysis and so on, find out that indeed, beam A is statistically so mixed, that its coherence length is too short to see an interference pattern.
But of course you can now do ANOTHER interference experiment with beam A, which is within the coherence length of that beam, and then you WILL of course find a pattern. Only, THIS specific interference experiment hasn't gotten anything to do anymore with the original aim of the entangled beams, which was, to be able to "cheat" on the interference mechanism. Indeed, now you will find out that the entangled beams are such, that beam B hasn't gotten anything to say anymore about which slit beam A might go through. In other words, the two slits of beam A are now such, that the states corresponding to the new slits are not entangled to orthogonal states in beam B. No measurable quantity on beam B can tell you now through which slit you went at A.
Let us go back to our original interference setup at A, so that there is a potential measurable property of beam B that tells us through which slit beam A went. No interference pattern should occur in this case.
Now, what if you "destroy" beam B, or whatever measurement you do on it that will make it impossible for you to restore the "which slit" information ?
It won't change anything: beam A, as seen just as a single beam, hasn't changed, and is still the statistical mixture it was before B got destroyed/measured/whatever. As such, its coherence length is not good enough to produce an interference pattern. It is not by doing something with beam B, that something will change on the A side.
However (and these are those famous DQE experiments), you could do a measurement on beam B, which makes it impossible to restore the which-slit information, simply because it is an incompatible measurement.
Now you can USE this information obtained by this measurement on beam B, to go and SUBSAMPLE the hits you found on beam A. And THEN, it is possible, USING THIS SUBSAMPLING, to find in the selected dataset an "interference pattern" on the A-side. But this pattern is a *subsample* of the total pattern on side A, which didn't show any interference overall.
Now, imagine we do this, using the "narrowed-down" slits which made beam A have an overall interference pattern. You can now do on beam B what you want, and use this information to subsample the data on the A side as much as you like, you will ALWAYS find the same interference pattern on the A side. Why ? Because the interference pattern on the A side is now due to a state which FACTORED OUT and is hence not entangled with any property on the B side. So there is no specific correlation that will appear.
EDIT: upon re-reading some of the posts here, I would like to make something a bit more clear, and I'm not sure whether it is RandallB or JesseM who is (mis)understanding something, or whether there's an empty dispute.
It is true that locally, one cannot see any difference between an "entangled" and a "non-entangled" beam. However, a non-entangled beam might be a pure beam, while an entangled beam will ALWAYS (APPEAR TO) BE A STATISTICAL MIXTURE OF SOME KIND.
But when these statistical properties are accounted for, there is indeed, locally, no way of discriminating, by no experiment, between a "truely statistical mixture of non-entangled beams" and "one arm of an entangled beam".
