Light in a vacuum of space travels at 3.0*10^8 meters per second. When light enters a medium that is not electromagnetic energy while it is also not a worm-hole, the light will tend to travel at a speed that is less than light speed. For instance, when light strikes air, the light not only bends to a slight extent, it will also slow down to a correlative extent as well. Once that light strikes the air, it will scatter -- while then subsequently tending to re-quantize to form light again. Once the light reforms as light again, it will tend to travel in what amounts to as its given "tense of bend", yet in segmentations that are each of a relatively straight line, -- to where the said light, as it is here to be as is according to Snell's Law, is to then to go just slightly less than what light speed would be in a theoretical vacuum, as the so-eluded-to electromagnetic energy is to travel in the direction of "least time," as it is to only slow down and change direction, after each of such scatterings of the said light upon the so-eluded-to Calabi-Yau phenomenology of the said air molecules that it is to strike in a Gliosis-based manner over time. For example, let's say that the given air was homogeneous in density, and that the light that I am referring to here did not have to significantly re-scatter again in the air, as the given light is here to be propagated downward toward the earth. The light in this case is propagated towards the face of a body of water. When the light strikes the water initially, the light will scatter, while then re-quantizing back into a beam of light that bends as is according to the density of the water -- and slows down as is according to this same density of the water. The beam of light may be able to do this, if it is also not scattered by any plain kinetic energy, -- as other beams of light are to be inter-playing in this case scenario as well. This beam of light may propagate until it is fully absorbed, most potentially by some alterior Calabi-Yau space of mass.
I will continue with the suspense later! To Be Continued! Sincerely, Samuel David Roach.
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