jimmysnyder said:
This is quite a coincidence. I have been reading the book Photons and Atoms by Claude Cohen-Tannoudji et.al. and had stopped in the middle of page 215. Now I picked it up for today's reading and get to the following near the bottom of the page (slightly edited):
For example, a single-photon state which is a statistical mixture of eigenstates |1_1, 0_2> and |0_1, 1_2> with the weights |a|^2 and |b|^2 does not give fringes in w_1 (single counting rate) whereas these are observable with the superposition state a|1_1, 0_2> +b|0_1, 1_2>
Can we look for interference fringes in the wave-like properties of the incoming particles?
In order to distinguish a statistical mixture and a superposition, you have to work in *another basis*. In the explanation I gave below, I was assuming that the two analysers are lined up (at Alice and Bob). If they aren't, things are slightly more complicated, but the result is the same.
Indeed, consider this. The singlet state can be written as a superposition in any eigenbasis, it will always take on the same form:
|z+> |z-> - |z-> |z+> = |n+>|n-> - |n->|n+>
So if Alice put her analyzer along Z, we get, half of the time, that she obtained a + and half of the time that she obtained a -.
In other words, we get 50% of |z-> at our side and 50% of |z+>.
If, on the other hand, Alice put her analyser along the n axis, we get 50% of the time an |n+> and 50% an |n->.
Now, imagine that we (bob) measure along the m axis, which makes theta_m degrees with the z-axis.
In the first case, (Alice along z), in 50% of the cases, we get cos^2(theta_m) chance to find m+ and sin^2(theta_m) chance to find m-
(that's the Born probability for spin 1 particles, when we have a state |z+>, and we do a measurement along |m+> and |m->).
In 50% of the cases (we received a z-) we have sin^2(theta_m) chance to find m+ and cos^2(theta_m) to find m-.
Overall, we find 0.5 (cos^2(theta_m) + sin^2(theta_m)) = 0.5 chance to find m+ and 0.5 chance to find m-. I think you see that we also get this result when Alice measured along n (change theta_m into theta_(mn), the angle between the n axis and the m axis).
If Alice didn't measure anything, then we receive the original singlet state, and there too, no matter along which axis, we find 50% up and 50% down.
This is not a coincidence of this particular setup. It can be shown in all generality (long ago I posted the proof here as an attachment, but I can't find it again): any measurement on a particular part of an entangled system gives exactly the same statistics, independent of whether, and which, measurement is performed on the other side.
What is peculiar, are the *correlations* between the outcomes at both sides. But the projected statistics of the measurements on each side are independent of what is the measurement performed on the other side.
You've almost re-discovered the EPR Bell paradox !
That's good 
