Yet another clarification needs to be made. The "built path" for light, through a self assembling lyotropic medium, exists for only so long as its tendency to dissolve. It has latency. The tendency of its lyotropic nature for dissolution is quite quick, and is why the large transverse path dissolves immediately while the center of tessellation can remain an open waveguide (due to the instantaneous "refresh" of its tessellated wave form).
The oscillation of the photon energy is confined to two waveguides, which themselves have "bifringent" properties. Thus, what we might interpret as the "amplitude" of the energy in the outer waveguide is simply the geometry of distance, and is large, while that geometry is much smaller in the inner waveguide. Thus, the terminology of "tiny waves" associated with both full-on reflexive entangled quantum connections, and what I call "half cycle" quantum connections, the latter not being "entangled" - but still use exactly the same mechanism for information exchange.
This two factor mechanism is why it requires bifringent material with hexagonal crystallography to initiate quantum connections. It's two waves at once, with the inner one confined to quantum-sized geometric spaces (undetectable in Einstein's day, which is why he couldn't find them). The tessellation of a lyotropic medium that is bifringent, and possessing of a hexagonal crystallography, easily creates bimodal or trimodal mechanisms for light transmission, due to it's capacity for nested waveguides.
The tendency is to call the inner energy transfer a "wave" but it is not exactly such a thing, as the almost instantaneous speed that light possesses on a pre-existing path makes that transfer more of a singular pulse of energy with angular momentum, as in a wilberforce pendulum.
Yet another clarification needs to be made. The "built path" for light, through a self assembling lyotropic medium, exists for only so long as its tendency to dissolve. It has latency. The tendency of its lyotropic nature for dissolution is quite quick, and is why the large transverse path dissolves immediately while the center of tessellation can remain an open waveguide (due to the instantaneous "refresh" of its tessellated wave form).
The oscillation of the photon energy is confined to two waveguides, which themselves have "bifringent" properties. Thus, what we might interpret as the "amplitude" of the energy in the outer waveguide is simply the geometry of distance, and is large, while that geometry is much smaller in the inner waveguide. Thus, the terminology of "tiny waves" associated with both full-on reflexive entangled quantum connections, and what I call "half cycle" quantum connections, the latter not being "entangled" - but still use exactly the same mechanism for information exchange.
This two factor mechanism is why it requires bifringent material with hexagonal crystallography to initiate quantum connections. It's two waves at once, with the inner one confined to quantum-sized geometric spaces (undetectable in Einstein's day, which is why he couldn't find them). The tessellation of a lyotropic medium that is bifringent, and possessing of a hexagonal crystallography, easily creates bimodal or trimodal mechanisms for light transmission, due to it's capacity for nested waveguides.
The tendency is to call the inner energy transfer a "wave" but it is not exactly such a thing, as the almost instantaneous speed that light possesses on a pre-existing path makes that transfer more of a singular pulse of energy with angular momentum, as in a wilberforce pendulum.