Let us initially consider a set of orbifold eigensets -- that work to comprise the holonomic substrate of one given arbitrary molecule. Let us next consider the molecular condition, that any set of one or more atoms -- namely in this case, here, a molecule, -- is going to bear at least a certain scalar amplitude/scalar magnitude, of a tense of both an internalized and an externalized vibrational-oscillatory-based mode, as such a molecule is to here be undergoing its so-eluded-to tense of a Majorana-Weyl-Invariant-Mode, at its proximal local reference frame, over an allotted respective period of time. As any given arbitrary molecule vibrates -- such an oscillation-based mode, will tend to work to form a certain Calabi-Yau scattering of the electrostatic eigenindices of that molecule, in so as to help to allow some of its correlative component electrons, to undergo the Fujikawa Coupling -- in so as to help at working to form proximal localized heat energy. Often, especially with luminescent molecules, -- the proximal local presence of infrared or heat-based photons, will help to encourage that general genus of the Fujikawa Coupling, that is to here work in the formation of white or visible light. So here, as that general genus of a gauge-transformation is to happen, in so as to work to form infrared or heat-based photons, there is to then, as well, be the occurrence of the spontaneous activity of the general genus of a gauge-transformation to happen, that will work to form photons of visible light. In this manner, that general genus of activity, that works to form the multiplicit gauge-transformation that is related to the formation of heat energy, is to here, with luminescent-based molecules, to work to form the multiplicit gauge-transformation that is related here to the formation of visible light energy. Often, a heat differential, that is to be applied to the here respective given arbitrary luminescent set of molecules, is what will work to set-off the so-eluded-to gauge-transformation-based response.
I will continue with the suspense later! To Be Continued! Sincerely, Samuel David Roach.
No comments:
Post a Comment