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by
Vernon Brown
November 9th 2009
Consider that diminished electromagnetic fields from photons permeate all of space, even that space that is inside matter. The reason the fields can permeate all space is that they are too weak to interact and so are almost invisible to matter. Photons moving
through these diminished fields reach their saturation amplitude with the help of the fields. Saturation amplitude is therefore reached at an offset toward increasing field strength of the diminished fields. That is gravity according to photon-theory.
Now, with that understanding we are faced with a new realization. The photon needs to transition through less overall amplitude to become saturated. This means that the peak to peak amplitude transition of the photon is less in a gravity field than it is outside the gravity field. Less peak to peak amplitude means less energy. So, a photon must lose energy to an ambient gravity field.
This loss of energy must manifest itself as a shift in wavelength. The red shift is accumulative, so that once shifted the photon does not regain its lost energy. Some areas of the cosmos contain more ambient gravity than others. We should therefore expect the amount of red shift in light from distant objects to vary according to the amount and the density of gravity fields they penetrate.
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