Figure 2. There are two images: A and B. Both images show that when a photon detects an electron’s location, it collapses to a new wave source. If this is true, the wavelength of the photon should determine the width of the region for the new source for the electron wave. A photon with a wider wavelength should result in a wider region where the new wave source begins. Also, the electron wave emitted from this would have a narrower wave spread, as exhibited in image B. A photon with a narrower wavelength should result in a narrower new wave source. Moreover, the electron wave emitted from this would have a wider wave spread, as exhibited in image A. This would not happen if the electron collapsed to only a particle. A particle passing through a narrower region would not come out of that region with a greater spread. Instead, it should come out with a narrow spread, which would be similar to the narrowness of the region where the particle is detected. Summarizing, if a wave collapses to a particle when detected, a beam will be produced that is narrow like the region where it was detected. On the other hand, if the wave collapses to new wave source, the narrower the region where it is detected results in a beam spread out more.