9) The "roll" of superstrings forms an orbital effect that, along with the spin of the said superstrings, allows for the supermagnetism of the substringular. Such a spin-orbital momentum is reverse-fractored into the "S" of an electron which forms the magnetic fields of the globally distinguishable.
10) Point particles redistribute their interial fields after sets of their radial motion in such a way that their whole neighborhood of a point particle (the region where the point particle's field indices are Poincaire to the general region of the said point particle) is touched by mini-string after each set of such radial motions that is equal to the reciprocal of the fraction that the said point particle neighborhood described is void of being completely compactified.
11) Since point particles redistribute their mini-string sundry times each Planck Moment, the point particles appear as completely filled in the globally distinguishable, even though these aren't completely filled at each sub-metric in the substringular. Such reformation causes the kinematic plane of the said point particles to be a majorized plane which causes space-time-fabric to bend over the covariantly kinematic sets of Fourier Transformations that allow phenomena to interact.
12) When norm states or other organizations of point particles are redistributed from point commutation into a covariantly homeomorphic conglomeration that involves inexact and nonlinear differential eigenstates, then such an activity will cause these states to convert into a vacuum.
13) When scattered point particles of a vacuum of space are converted into linear and exact differential eigenstates, these may then form superstrings.
14) When the multiaxial of a superstring's redistribution through a Fourier Transposition is of a mass under light speed, then the spinor coniaxial of such is orphoganal relative to light when compared under a scalar that joins these via supplementation that is Yakawa yet not Gliossi. Such an orphogonal relationship helps to cause the condition of a mass' differentiation through time to be relative to light.
15) When a superstring is unorientable during both the Bette and Regge Actions, then the spinor coniaxial of the said superstring is made orphogonal to what it had before. An unorientable superstring becomes tachyonic.
16) Only light may "catch up" to light. Tachyonic flow is always transient, and involves the adjustment of space-time-coordinates. So, tachyons do not really "catch up" to light unless it is of a form of electromagnetic energy.
17) A "normal" string is multiplicitly parallel to the fabric of point particles. This is because "normal" points obey Noether Flow. Although Noether Flow involves a type of Planck Differentiation per instanton, the general flow of point particles is under light speed. This is because the spinor coniaxials of the multiaxial of "normal" point particles is orphogonal to that of electrodynamic energy, since electrodynamic energy is propagated, and, therefore, is not really projected like a mass is projected. This is why mass moves relative to light, and thus, can not "catch up" to light. Again tachyonic motion involves a redistribution of space-time-coordinates and/or the reconnection of relatively distant loci of space.
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