Once light is scattered, the said electromagnetic energy travels while initially working to bear a Kaluza-Klein light-cone-gauge topology -- as the directly corresponding scattered photons are to here to temporarily be of an entropic nature. This means that the light-cone-gauge eigenstates that are here to work to comprise the said entropic photons, are -- over the course of bearing a Kaluza-Klein topology -- to be of an abelian geometric nature. When the light-cone-gauge eigenstates that are of a set of superstrings, are to be of an abelian geometric nature -- this means that those second-ordered light-cone-gauge eigenstates that are here to work to comprise each of the individually taken discrete energy quanta, that are here to work to comprise the so-eluded-to orbifold eigenset (and an orbifold eigenset is a set of superstrings that operate in so as to perform one specific function), are to bear a relatively supplemental translation across the correlative Laplacian-based Lagrangian in which these are to be relatively positioned at, over the directly corresponding individually taken iterations of instanton, in which these are to have an abelian geometric nature. When electromagnetic energy is to be re-quantized, it is then to work to re-attain a Yang-Mills topology. This means that the individually taken light-cone-gauge eigenstates that are here to work to comprise the said electromagnetic energy that is here to be re-quantized, is then to re-attain a non abelian geometric nature. This will then consequently mean that the second-order light-cone-gauge eigenstates that are here to work to comprise the individually taken discrete quanta of energy impedance, are then to bear a relatively sinusoidal translation across the correlative Laplacian-based Lagrangian in which these are to be positioned at, over the directly corresponding individually taken iterations of instanton in which these are to have a non abelian geometric nature. I will continue with the suspense later! To Be Continued!
Sincerely, Samuel David Roach.
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