I am calling attention to three experiments that I have posted on Reasearch Gate which seem to indicate a nearfield generation of photon path interference as opposed to interference at the points of detection and actualization. I would like to see comments from experts in this field as to if these results contradict quantum theory or not.
Go to "Anomalous Photon Interference" at Research Gate, under author Barry Fleagle, and scroll down to the "Dark Edge Double Slit Experiment". In this experiment the photon path to one of double slits is unrestricted while the path to the other is obstructed early; but a double slit pattern is still produced. Can paths already directed towards the illuminated slit generate additional, probable, parallel paths to the dark slit or a broader probability field?
Go to "Polarity and Photon Interference" at Research Gate, under author Barry Fleagle, and scroll to the "Polarized Double Slit Experiment". In this experiment some of the light passing through a slit with a 90deg. filter forms an interference pattern with some of the light passing through a 45deg. filter.. However, when only some of the light from the 90deg. filter passes through a later 135deg. filter, which restricts the light from the 45deg. filter, there is still a double slit interference pattern produced. Does interference occur early, prior to the 135deg slit? If-so, would this require actualization of photons in the near field?
Go to "Experimental Determination of Photon Interference Point", under author Barry Fleagle, and scroll down to the "Narrow Horizontal Angle Experiment". In this experiment separate photon paths converge at a slight angle in the near filed but go on to display an interference pattern at widely separated detection screens. Does this experiment complement the previous experiment.
Note: These results may not be in conflict with the Bohr model, but if they are, there are many others that are not. I am interested in analysis by experts in this field.
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