So, protons are bigger than electrons. This is true both in terms of size and in terms of mass. Since a proton has more mass than an electron, it has more two-dimensional superstrings associated with its mass than an electron does. Each fundamental particle just under the level of the proton is a certain thing that describes a three-dimensional delineation in the globally distinguishable. In the subsringular, these "packages" that are here have such delineations that are actually sequences of one- and two-dimensional strings. Each of such sets is in an order in a majorized plane. Each of such stringular encodements is just a segment of its correlative substringular string. (I'll explain this later.) The order of such a set is a thin band of strand-like phenomena and hoop-like phenomena that are very limited in side-to-side transversel sway besides the basic vibration of the said superstrings. It is limited by the Caucy Ward conditions of the given world-tube that is affiliated with the said superstrings. The whole set of such sets that comprises the proton is an association of substringular sequences that exist on separate parts of a tori-sector-range (one of such per part). The symmetrism of these sequences bears a wave-tug that is mini-string that goes from not fully compactified to fully compactified once its surrounding pressure is exerted upon it in an abelian way in a manner that is like a "party whistle" that acts thru any holomorphic operand that is vacant. (Stuff with a perturbative symmetrism will push the described mini-string into an anharmonic mode.) Please wait for the physical example that I will describe to you during the second post of this session so that you will have a better feeling for the concept that I am trying to let you know.
You have a phenomenal day!
Sam.
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