The condensation neutrino is probably the dark matter particle. The model predicts the dark matter particle. We have simultaneous attraction and repulsion of the electron by the proton. The six negatively oriented quanta are present, and would prevent the electron from being fully pulled into the proton. Even though they are canceled out, they still exist. The 'nu' notation of 12n6u says that there are six negatively oriented quanta within the proton. The model predicts the proton has hidden negative charge. The proton has a hidden full negative charge, and this is why the electron is not fully pulled into the proton. It leaves a net of six unmatched positive quanta, for a net charge of plus one, just right to bind to an electron. The 'nu' notation of the proton is 12n6u. We can construct the proton using three quarks: The proton is composed of both negative and positive charges, with the net charge being positive one. The 'nu' notation is 9n9u all components cancel. The system of three quarks gives a neutral charge. Notice that no two quarks can fully attract, or repel another. All the component quanta, within the system of three, are cancelled. Let us start with the neutron.īy combining two down quarks and one up quark, we get the neutron. We can use our particle model to construct protons and neutrons. We would find that combining all pairs of particles and their anti-particle will result in annihilation due to unrestrained attraction. There is nothing to stop the particles from being pulled together. When a particle meets its antiparticle, all the quanta are able to unite and pull together. There is nothing to stop them from pulling together fully. IN this example, we place an electron near a positron, and we find that all six quanta of either particle are able to bind to, and attract each quanta of the other. We can use the model to explain particle-antiparticle annihilation. This system gives us all the known electrical charges, explains fractional charges, and produces the anti-particles. Click on the table to see it more clearly. This produces all the known electrical charge arrangements of elementary particles. A list of all the combinations of six orientations of the quanta of space surrounding the center. With the 'nu' notation, we have underlined the pairs of spin that cancel each other, allowing for a more rapid assessment of the net charge of the particles. The following table gives the arrangements, charges, and associated particles. This would give us a net charge of minus two-thirds, corresponding to an anti-up quark. If five face outwards, and one inwards, then we have a net of four of six facing outwards. A full charge, of negative one, occurs when all six of the bound quanta, or atoms of space, are oriented so that their negative poles face outwards. We find that if six atoms of space are assembled to form a particle, we can create all the elementary particle charge relationships. Fractional Charges, Particles, and Anti-Particles We will represent this orientation with an 'n'. In the 'Positive' example, the south pole faces the center, and it is the north pole that faces outwards. We will use the letter 'u' to represent a negative orientation. In the 'Negative' example, the north faces the center and it is the south pole that faces outwards. The black spheres, or circles, represent the particle centers. We can create a notation for these arrangements to allow us to use a text-based description of the arrangements. Six sides per particle gives us six bound orientations.įrom this, to make drawing easier, we can place all six atoms of space in a 2D representation, as such:Ī 2D representation of the 3D arrangement. If we allow each particle to have six sides, or points of attachment, we get: When the same poles face each other, spin is opposed, and the units would be repelled from one another. When opposite poles face each other, they can unite in their spin. If similar poles are facing each other, the spins would not mesh, but repel, as shown in Figure 2.įigure 1: Attraction. If opposite poles face each other, we have attraction, as shown in Figure 1. In the following figures, we define the black sphere as the center, or point of attraction, and the white sphere as the atom of space. This simple system explains fractional charges and antimatter. If space is composed of 'atoms of space', and these atoms of space have spin, we can combine them to create units of matter that have electrical charges that match what we see with elementary particles. The Basis of Electrical Attraction and Repulsion
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