FTAAN, Session 14

For the one-dimensional mass of an electron, the superstrings involved are one-dimensional superstrings. The given superstrings are vibrating strands. Anything that has mass has a degree of conformal invariance. Anything that has mass has a sense of Yau-Exact condition. Yau-Exact conditions are conditions of a superstringular phenomena being hermitian and non-perturbative. A condition of mass or a condition of Yau-Exact conditions generally is a situation in which the superstrings that comprise the mass are not superconformal. These conditions of conformal invariance that are not superconformal involves a kinematic tense of superstrings that, besides the given kinematism, obey simailar locus to that of superconformal invariance. Let us consider the motion and conformalism of one-dimensional superstrings that are conformally invariant even though these are not superconformally invariant. A one-dimensional superstring arbitrarily exists as a component of the mass of an electron. The given one-dimensional superstring is moving kinematically in a spin-orbital, radial, and transversal directoralization. The whole electron as a unit, given its charge, relative to the protons of the nucleus is moving in a spin-orbital, radial, and transversal fashion. The given one-dimensional superstring is Yau-Exact. The given superstring, in and of itself, is conformally invariant in spite of the motion of its corresponding electron as a unit. The given one-dimensional superstring begins is a norm position relative to the holomorphic direction. Relative to the polarized holomorphism, the given superstring angles to the left at the next iteration. The given superstring then angle to the straight at the next iteration. The given superstring then angles to the right at the next iteration. The given superstring then angles polar norm (straight) at the next iteration. The given superstring then angles holomorphically at the next iteration. It then angles polar norm (straight) at the next iteration. It then angles antiholomorphically at the next iteration. It then angles polar norm at the base and top relative to the holomorphic position (straight) at the next iteration. This ninth iteration begins the second series of this associated sequence of superconformal invariance. In the meanwhile, the eletron's string here (one of 511,000 superstrings related to the mass of an electron) will propagate transversally spin-orbitally, and radially as the electron differentiates as a charged unit. This will continue until the given electron is electrodynamically, or otherwise physically, perturbated. So, an electron as a unit may often be conformally invariant in terms of its transversal momentum, while the electron as a unit may undergo the described spin-orbital/radial superconformal invariance at the same time, as long as the superstrings of the given electron are then all obeying Chan-Patton rules. llllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllllll