Light-sequences (back to light)
The graphic shows sequences of lightprocesses. The white dots of space and the green dots of form (photon) share the same place. In this graphic the white dots are depicted a bit left from the green dots to show, that space flashes first and form follows. In this graphic the lightprocesses are animated by an ongoing animation, e.g. from a light-bulb. Therefore the processes overlap continually. Graphics with one-time animation, e.g. from a quantum leap of a single atom, are shown on the
next pages L1 - L7. There you can see, that each photon arises BIG BANG-like from the not-manifested potential and dissolves back immediately after its manifestation. This rapid dissolving animates the following photon to arise, which brings about a sequence of newly arisen photons, which is depicted here in the graphic. Photons in this sequence just appear and disappear flash-like, so that none of them has a chance to move forward. But if photons don´t travel forward, how could we then measure a velocity of light? In this quantum model the motion of light would result from the fact, that each new photon appears in a set distance from the place, where the preceding photon has disappeared. When all these new photons appear sequentially with a set distance to each other, it looks as if a light beam is moving. What we measure as the velocity of light is not the velocity of one photon moving, but the velocity, which results from the sequence of photons, which appear with distance to each other flashlike with the frequency of the respective light.
The graphic shows the sequence of photons in the medium air. All photons have the same distance to each other. The result will be a constant velocity of light. If the light beam then enters a body of glass, the distance must be shorter, because the velocity of light in glass is reduced. But how "knows" the photon, what distance to take. The information lies in wisdom of the not-manifested potential. And because photons arise Trillions of time per second as new photons from that source, the information is available always fresh for each photon. In that way light also "knows", that it has to take the longer distance again, when leaving the glass body, to immediately speed up in air as medium.