Friday, January 19, 2018
Session 11 Of Course 4 -- Why Charges Bear Their Correlative Charges
Protons are positively charged particles that have a small amount of mass. Protons are made up of quarks and leptons. Electrons are made up of three leptons each. Protons generally are the simplest particles that exist with a charge that is just as positive as an electron’s charge is negative. It has a lot more mass than an electron, and its residual energy discharge does not form light. Electrons tend to move faster than protons, and electrons spin a lot more antisymmetrically than protons. Electrons each have a fractional spin, while protons each have a whole spin. A particle with a negative charge will have the opposite spin holomorphicty than an adjacent particle with a positive charge. The J is related to the symmetrism of particles, for the reason that J involves the spin-orbital-interactions of particles. As stated, J is also related to the electric field of a given particle, since, J is related to the angular momentum of a given particle. Angular momentum is related to spin-orbital-interaction, since the directoral impetus is influenced by the way something spins and orbits. (The way something goes around influences the direction that it incorporates and the object’s drive in that direction.) The electric field is that field that is most influenced by its charge. Since electrons that are adjacent spin antisymmetrically in an atom, and antisymmetric is negative of symmetry, and this symmetrism is influenced by J and thus the charge of an electron, and the holomorphism of the orbit of an electron’s transversal motion is antiholomorphic relative to the directoralization of the given electron’s path around the nucleus of an atom, the charge of an electron is negative. Since protons’ spin in an atom tends to be more symmetric, and the orbital vibrations of protons is holomorphic relative to the general Laplacian setting of an atom, a proton has a positive charge. Electrons spin antisymmetrically in an atom because of their fractional spin, high velocity, and also because of the dynamics of their fields. The electric fields of electrons tend to work on the world more than the electric fields of protons. Remember how light is the result of the recycling of differential geometries? Remember how the residual discharge of electrons is light? Electrons do this because these are a point mass of charge versus the mass that appertains to protons and neutrons. Well, this is why electrons have more dynamic fields that protons. These electrons thus need to be geometrically arranged so as not to interfere with where these are at. Electrons, to exist in a spot, have to be in their own spot. Since their fields are more dynamic, they must spin antisymmetrically to adjacent electrons of the same atom or else these will collide fieldwise. This description of an electric field would also help to describe the magnetic field, since magnetic fields curl around electric fields. If two adjacent electrons of the same atom were to be perturbated to attempt these to spin symmetrically, the electrons, instead, would find a new localization, since two things cannot occupy the same spot at the same time. The field dynamics of subatomic particle is influenced by the velocities and directoralizations of these selfsame particles. The velocity of a particle influences the field associated with it. Thank you for enjoying this session. Have a great day! I will continue with the suspense later! To Be Continued! Sam Roach.
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