Session Eight Of Course 14

Electrons and neutrinos are examples of fermions.  Fermions have a fractional spin.  Strings that comprise fermions contain some open strings.  Open strings are one-dimensional strings.  One-Dimensional superstrings are vibrating strands.  So, electrons and neutrinos are made in part of strand-like one-dimensional strings.  Plain kinetic energy is composed of one-dimensional superstrings.  So, the superstrings that work to comprise plain kinetic energy are strand-like open strings.  Electrons are considered to be the sub-atomic particles that work to form  point-based mass.  This is even though neutrinos display a small amount of mass.  Electrons work to display the link between mass, plain kinetic energy, and electromagnetic energy.  Electrons that are at a theoretical rest have (are composed of) 511,000 Planck phenomena.  This is although an actual electron is never completely at rest in the real world.  As electrons move, these said phenomena have more mass than these have at their rest mass, and, these then also have added Planck phenomena at this point due to their added kinetic energy -- due to the condition that motion eludes to energy, and, added energy is a condition that requires more Planck phenomena that are to be involved here.  The faster that a given arbitrary electron spins and/or travels radially and/or transversally, the more Planck phenomena that the said electron has, due to their extra mass (due to the activity of the directly corresponding Lorentz-Four-Contractions), and, the more Planck phenomena that these said electrons have, due to their extra kinetic energy (which is apparent due to their increase in motion per time).  The mass of an electron is centered at the neighborhood of the locus of the said electron itself, whereas, the plain kinetic energy of an electron is focused in the neighborhoods that surround the mentioned neighborhood of the locus of the said electron itself.  This is part of why the Heisenburg Principle works as it does.  The rate of an electron that is spinning around a nucleus -- that is in static equilibrium -- is pretty constant, except for the pulse of the rotation of the said electron around the said nucleus -- due to the spin-orbital and the radial momentum bearing a fractional-based spin that works in the directive of a harmonic-based oscillation.  When an electron undergoes a charge, the accelleration, the transversal, the radial, and the spin-orbital momentum of that electron alters temporarily in an anharmonic manner, and, this forms a transient alteration or perturbation in the electric field of this given case.  In the real world, an electric charge will perturbate a group of electrons, which here causes these to differentiate anharmonically -- initially -- in terms of transversal, radial, spin-orbital, and in terms of the overall angular momentum that is involved here.  This happens in a codifferentiable-based manner that bears both a different basis of chirality, and in a manner that here involves a different local directoral-basis.  Once the new electric charge is maintained, the differential kinematic-genus of the affected electrons will here become harmonic, and, the perturbative factor that is now involved will no longer engage in any immediate added covariant Njenhuity.  The superstrings of the plain kinetic energy of the said electron that are Gliossi to the Poincaires of their immediate field are open vibrating strands of discrete energy permittivity, while, the superstrings of the mass of the said electron that are Gliossi to the Poincaires of their immediate field are closed vibrating hoops of discrete energy permittivity.  To Be Continued!  Sincerely, Sam Roach.