mangurian said:
I thought the angle of the spinning vectors used by Feynman in "QED" implies an initial phase relationship between photons in deriving an interference pattern. Even if the term is not "coherence" isn't there an assumption in his computations that the pattern is due to the angles of the spinning vectors when they are added at a receive point. IE., in order to make this calculation and generate a "classical" interference pattern, you start by assuming the vectors are aligned (in-phase) at the source point. Then the final vectors are computed based on the possible "paths" of each photon to the receiver.
I know this is going to sounds picky, but the reasons why I object to the terms "coherent photons" and "incoherent photons" is as follows...
- You can have spatial coherence and temporal coherence. Waves might be spatially coherent but not temporally coherent and vice-versa.
- Waves gain and lose coherence based on the system - it is a dynamic quantity, not a static one.
- Coherence is not a binary quantity, but a continuous one.
It's just one of those things that tends to lead to confusion, which is why I try to avoid labeling waves in this way. Adding photons to the mix further compounds the problem - diffraction can be adequately explained by classical theory without resorting to QM.
Your understanding (and Feynmann's layman explanation as you have presented it) is accurate. Note though how the phase relation of each photon is explicitly stated in time and space, which is the correct way to go about describing coherence!
clem said:
Separate photons from the light are not phase coherent.
This is not correct. You can "enforce" spatial coherence by only permitting a small portion of the wavefront to enter your detector (i.e. through the use of a slit or pinhole). In fact, this is what Young did in his famous experiments.
mangurian said:
I am not sure I posted this in the correct forum...should have been under quantum.
Nope, this is the right forum

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Claude.