The Electron and The Neutrino

Aatucagg believes that local space is relative. Local space is flat space that is large in comparison to the matter residing within its boundaries, and the same local space is curved space that is small in comparison to matter residing within its boundaries. This leads to the concept that space on an atomic level is flat space, and space on a macro level is curved space. So, matter should react in a similar way on an atomic level as matter on a macro level. This means that the matter of an electron leaving the orbit of an atom should behave in a similar way as the matter of a planet leaving the orbit of a solar system or galaxy. Just as the matter of a planet converts to light as it moves away from the center of a solar system or galaxy, the matter of an electron converts to light as it moves away from the center of an atom. Proof of this may exist in the fact that electrons moving away from the center of an atom do not contain enough energy to maintain the conservation of energy. In other words, when an electron moves away from the center of an atom it appears that energy is being lost, which violates the law that total energy can not be created or destroyed. To get around the problem of missing energy, a scientist by the name of Wolfgang Pauli came up with the idea of the neutrino. He proposed the concept that the missing energy of the electron was contained within the neutrino, so that it was not the electron alone moving away from the center of the atom, but every electron moving away from the center of an atom had an accompanying neutrino moving away from the center of an atom. He reasoned we could detect the electron because it had mass, and we could not detect the neutrino because it had no mass, therefore, the electron carried mass-energy and the neutrino carried momentum-energy. It was later discovered that the neutrino consisted of three flavours: electron neutrino, muon neutrino, and tau neutrino. But in order for the neutrino to change from one type flavour of neutrino to another requires time. This turns out to be a problem, since only a particle with matter can experience time, therefore scientists had to revise their theory and allow the neutrinos to have mass. AAtucagg believes it is possible for a neutrino to have flavours with out the need to be composed of matter. This can be accomplished if electrons and neutrinos are actually the same particle, with the electron being composed of the spacial and temproal matter of the particle, and the neutrinos being composed of the temporal matter of the particle only. In this way, it is the matter of the spacial component of the particle that influences the flavours of the temporal component of the particle. Since mass is composed of spacial and temporal matter, and spacial mass is oriented parallel to the surface of space and temporal mass is oriented perpendicular to the surface of space, then the closer the particle is to the center of the atom the more it behaves like an electron and the further the particle is from the center of the atom the more it behaves like a neutrino. In parallel flat space near the center of the atom, the particle is an electron and exhibits only mass-energy. The particle will move through curved space as it moves away from the center of the atom and converts from an electron to a neutrino. The angle between the surface of space and the particle will determine witch flavour the neutrino will exhibit. At a sufficient distance from the center of the atom the particle will enter perpendicular flat space and the particle becomes a neutrino and exhibits only momentum-energy. This implies that in perpendicular flat space the neutrino is no longer under the influence of the matter of the electron, and therefore can not change flavour, which means it experiences no time. In other words, the particle in perpendicular flat space has converted into light. Therefore, it can be said that light is the 4th flavour of the neutrino and matter is the 1st flavour of the electron.

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Electron and Neutrino

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Electron and Neutrino