Electrons tend to stay in an orbit that conserves the most energy. When an electron can lose energy in order to become more stable, it does so by droping an energy level. When an electron loses a discrete amount of kinetic energy by the just mentioned dropping of an energy level, the released energy becomes a discrete quantum unit of electromagnetic energy in the form of a photon. A single photon is a Planck-like phenomenon that is tied via a light-cone-gauge eigenstate to a two-dimensional superstring -- the latter of which is tied to a substringular counterpart. When photons cluster into light to quantize, the individual photons spin and orbit each other in accordance with the wavelength of electromagnetic energy that these have just formed. The discrete plain kinetic energy of an electron has PLP that are tied to one-dimensional superstrings via a first-ordered light-cone-gauge eigenstate. In order for electrons to form photons, the one-dimensional superstrings of the said electrons that are released from the just mentioned electrons must turn into two-dimensional superstrings of discrete energy permittivity. This happens because the momentum of the given arbitrary electron going through the process of dropping an energy level works to push the ends of the initial one-dimensional superstring -- that is here an un-needed residue of that given electron -- inward toward each other via a genus of a Yakawa Coupling that is here known of as a Fujikawa Coupling. This happens in such a manner so that both ends of what was a one-dimensional superstring bend as is according to the Green Function in so that the norm-to-holomorphic end and the norm-to-reverse-holomorphic ends of the said initial one-dimensional string torque in a hermitian-based manner toward each other so that these said ends will then touch, rub, and curl upon each other to form the mentioned two-dimensional string that is here in the form of a photon. A photon is a discrete unit of electromagnetic energy. Electromagnetic energy is commonly thought of as light. As the one-dimensional string that I mentioned in this post converts into a two-dimensional superstring, the directly corresponding light-cone-gauge that is involved here unfurls to an extent to go from having five mini-string segment-like links to having ten mini-string segment-like links. The 120 loops that are directly involved here are temporarily unlooped during the said unfurling -- just enough to convert from having five mini-string segment-like links to having ten mini-string segment-like links -- and the mentioned mini-string segment-like links or strands are spaced-out along the topology of the said two-dimensional vibrating hoop (bosonic superstring) in a relatively smooth manner in both a spatial smooth, as well as happening smoothly over the metrical course of duration in which such a conversion of light-cone-gauge characteristics is happening. This is part of why photons are considered bosons and electrons are considered fermions.
I will continue with the suspense later!
Sincerely,
Sam Roach.
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