The whole "point particles" including the empty space of the points' homogeneous fields are really point particle neighborhoods. Do you remember me mentioning the Pauli Exclusion Principle and the Heisenburg Exclusion Principle? The Heisenburg Exclusion Principle basically says that you can not find or determine exactly where a very small particle is at and what it is giving off at the same time. The Pauli Exclusion Principle is basically that two things can not occupy the same spot at the same time. (Adjacent electrons must bear antisymmetric spin.) A typical point particle as its core density iterates and reiterates within a volume of roughly two to 10,000 times the volume that it would have if it was completely condensed. It does this iterating throughout the translation of its point particle neighborhood radii (consistently during iteration and Ultimon Flow). The point particle, as a density, is condensed oscillation. Condensed oscillation will tend to "want" to spring out when it is given a chance, just like a spring will spring out when it is released. The world-tube governs the Ward Conditions of the strings. Strings are the basis of the organization of point particles. So, a point particle will "want" to reiterate primarily in the relative center state of its neighborhood after the point iterates one radii of its neighborhood over the course of the substringular activity that involves the given point particle (when one considers 'the flow from iteration time to Ultimon time to be a blend of metrical activity). This is because the cross-section of the given world-tube will be holomorphically translated after during such a travel. Yet, this would leave one to 9,999 dispersed areas of locant that are not covered! No problem. After the point travels the given distance, it will iterate at all two to 10,000 states due to the majorization of the plane that the point traverses. This is because the point particle, in traveling the radii of its neighborhood, will curve in four directions besides its "0" dimensional framework. This is because the given point particle neighborhood is treated here as one of the simplest "three-dimensional" phenomenon that is curving in space to where it behaves like a "four-dimensional" phenomenon as the Ultimon cycles. Each added dimension adds a power of ten to the areas equivalently swept, since the world-tube bears 10 directly associated dimensions (explained later) and 10^0 = 1, 10^1 = 10, 10^2=100, 10^3=1,000, and 10^4=10,000. So, the point is at 10,000 different locations many times over the cycle of one iteration. (It is at one spot at a time, yet this is at a lower level of discrete. This is under regular Einsteinian motion. 1/10,000 of the condensed oscillation centered in a point particle neighborhood pulses radially after each iteration of the substringular.
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