Electrons may be viewed of as mass that is energy that is wave that is particle, at the same time. When an electron drops an energy level, while then returning to its immediately prior energy level -- a discrete amount of energy is then to be released from the said electron, in the form of a photon. A photon is a discrete quantum of electromagnetic energy. This happens, by the process of the directly corresponding one-dimensional superstring and its counterstring, that is released by the electron of such a case -- when it is tugged into bending in a hermitian manner -- to then be formed into a respective bosonic superstring and its correlative counterstring of discrete energy permittivity, -- via the Fujikawa Coupling, over a successive series of instantons. The so-stated bosonic superstring of such a respective given arbitrary case, is more associated with the particle nature of a discrete quantum of electromagnetic energy permittivity -- while the so-stated correlative bosonic counterstring of such a case, is more associated with the wave nature of a discrete quantum of electromagnetic energy permittvity. In the meanwhile, the respective light-cone-gauge eigenstate -- that is correlative to this given case, is altered from working to bear ten second-ordered light-cone-gauge eigenstates, to then working to bear only five second-ordered light-cone-gauge eigenstates ( as such said eigenstates are to then double-up in the Hodge-Index of the mini-stringular segmentation of their holonomic substrate, as to the cross-sectional thickness of the correlative chord-based topology of the so-eluded-to substrate, that is of the pheonomenology of such second-ordered eigenstates). The correlative Fadeev-Popov-Trace eigenstate, is to here be torqued by this overall process -- yet, it will tend to still bear basically the same general genus of its morphological topological substrate, over the course of the process of the so-eluded-to group-metric of the Fujikawa Coupling.
I will continue with the suspense later! To Be Continued! Sincerely, Sam Roach.
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