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Essay II B
The Particle Harmonic Formation
with comparisons atomic experimental evidence
107: Given point 105, once the electron position is established and now represents the open or advancing element of the harmonic process, then there is no need to keep the 675th overtone alpha wave of the proton as an incomplete alpha wave. The next harmonic step is then to complete this position as an alpha wave which clearly transfers control of the harmonic process over to the developing electron. The structure in FIG. 41 consists of 207 sub-particles consisting of 85 charged sub-particles and 122 neutral sub-particles.
108: Given point 70, there will exist an atomic structure consisting of 85 protons and 122 neutrons. The atomic isotope astatine 207 contains 85 protons and 122 neutrons. Astatine in listed as a 7A element but is more appropriately identified with Hydrogen as it contains a single proton in the electron structure. This identity is further enhanced when the next element (radon) is identified as an 8A element similar to Helium.
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109: Given points 62-108, the next step will be the completion of the alpha wave for the electron. The structure in FIG. 42 is composed of 222 sub-particles consisting of 86 charged sub-particles and 136neutral sub-particles.
110: Once the electron is firmly established as an harmonic process, then the neutral wave wire is extended to it’s optimal position which places the start of the electron at the 1800th harmonic. As stated previously the entirety of the evidence for this number is not shown. However, generally the mass ratio between the proton and electron is approximately 1:1800 and this number is effectively verified by the accuracy of the particle energy calculations.
111: Given point 70, there will exist an atomic structure consisting of 86 protons and 136 neutrons that will be identified as an 8A element. The atomic isotope radon 222 contains 86 protons and 136 neutrons and is identified as an 8A element similar to
helium. |
112: Given points 62-111, the next step will be the formation of the alpha wave pair consisting of one overtone alpha wave and one undertone alpha wave. The structure in FIG. 43 is composed of 226 sub-particles consisting of 88 charged sub-particles and 138 neutral sub-particles.
113: Given point 70, there will exist an atomic structure that contains 88 protons and 138 neutrons and is listed as a 2A element similar to beryllium. The atomic isotope radium 226 contains 88 protons and 138 neutrons and is a 2A element similar to beryllium. |
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114: Given point 70, additional evidence can be derived from the relative stabilities of the radioactive elements. Radon is the first structure to show any sign of stability. The highest stabilities of the previous radioactive elements are: Polonium 102 years, Astatine 324.6 minutes, radon 3.8235 days, Francium 21.8 minutes. Since polonium is a transition element we can eliminate it from consideration which means that radium is 2.6 million times more stable than astatine, 153 thousand times more stable than radon, and 38.6 million times more stable than francium. The justification for this massive increase in stability is that in the electron formation the isolated alpha wave is not symmetrical when compared to the proton structure. Symmetry can only be achieved with equality between overtone and undertone positions. Thus, when stable alpha waves are placed in the fundamental overtone and undertone positions of the electron, then true stability is achieved for the first time.
115: Given points 62-114, the next step will be the completion of the vector wave. The structure in FIG.
44 is composed of 244 sub-particles consisting of 94 charged sub-particles and 150 neutral sub-particles .
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116: Given points 62-114, the symmetry conditions imposed on the electron by the completed proton cause the electron to place neutral sub-particles in advanced wave positions in an attempt to create greater similarity between the electron and proton structures.
117: Given point 70, there will exist an atomic structure containing 94 protons and 150 neutrons and comparing to the 8A elements. The atomic isotope plutonium 244 contains 94 protons and 150 neutrons and has similar properties to 8A elements. In addition, as would be expected given the completion of the vector waves, plutonium 244 has one of the highest stabilities of the radioactive elements at 8.08E7 years. The stability occurs for 3 reasons: a complete neutron wire, completed vector waves, and color charge symmetry. The overtone and undertone vector waves are complementary or symmetrical (red-orange vs blue-green).118: Given points 62-117, the next step is the completion of the second vector wave. The structure in FIG.
45 is composed of 259 sub-particles consisting of 102 charged sub-particles and 157 neutral sub-particles. |
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119: Given points 62-118, the completion of the second vector wave eliminates the stability generated by the complementary nature of the pair of overtone and undertone first vector waves. The loss of stability combined with the need to generate overall symmetry with the proton results in a new wave process. Neutral sub-particles are stripped from the neutral wave wire and placed in advanced electron positions in an attempt to balance it with the proton. There are several stable bonding position s on the neutral wave wire. These are the octave positions of 1800 and their square roots.
120: Given point 70, there will exist an atomic structure composed of 102 protons and 157 neutrons with the properties of an 8A element and showing an extreme loss in stability. The atomic isotope nobelium 259 contains 102 protons and 157 neutrons , has properties of an 8A element, and has a half life of 58 minutes (as compared to 8.08E7 years for plutonium).
121: Given points 62-120, the electron will be completed in the same manner as the proton with the overtone 675th harmonic left as a partial alpha wave. At the atomic level the electron structure in isolation would equate to a bismuth atom
122: Given that the neutron decays into a proton, electron, and anti-neutrino, the structure in FIG. 46 is identified as the neutron.
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| 123: The structure in FIG. 46 breaks apart and releases 4 particles (FIG. 47). The proton reduces it’s 675th overtone harmonic from an alpha wave to a partial alpha wave releasing a charged sub-particle. The neutral wave wire then breaks in half releasing the proton which retains as much as the first half of the neutral wave wire. The second half of the neutral wave wire can no longer retain it’s connection to the electron and it breaks free (possibly the anti-neutrino?). This releases the electron. The electron and proton have identical structures with the exception that the proton retains a section of the neutral wave wire. |
124: Experimental evidence shows that the proton and electron are composed of quarks. FIG. 48 shows a simplified representation of the neutron in radial configuration. The radial design shows how quad-alpha waves are arranged in groups of 3 corresponding to the three quark structure of protons and electrons. In between the quarks are neutral positions (highlighted with a light gray). The neutral wave wire is shown as a thick gray line connecting the neutral sub-particles.
Comments on quark charge:
Two properties affect quark charge. The first is orientation. Quarks on one side of the harmonic circle will have an opposite charge from quarks existing on the opposite side. The second property is time sharing with neutral waves. Of the 3 quarks, 2 are composed of sets of 3 quad-alpha waves. The third is composed of double alpha waves separated by significant distance. These double alpha waves share time with neutral sub-particles resulting in waves that produce charge only half of the time.
The charge of the quark is produced by the 3 quad alpha waves. Within a particle, there are a total of 9 double alpha waves produced by the overtone harmonics, and 9 double alpha waves produced by the undertone harmonics. If the starting charge is defined to be +1 for the overtone original wave, and +1 for the order of undertone original wave, for a total starting charge of +2, then each double alpha wave will have a 1/9 charge. 6 double alpha waves will each have a +1/9 charge, and 3 will each have a -1/9 charge for each harmonic series. Combined, there will be 6 quad-alpha waves each with a +2/9 charge, and 3 distance separated quad-alpha waves each with a starting -2/9 charge. Because the distance separated quad-alpha waves only produce their charge half of the time, then their total charge is reduced to -1/9 charge. Each quark is formed from 3 quad-alpha waves. 2 quarks will each have a cumulative charge of +2/3 (+2/9 +2/9 +2/9), and the quark formed from the distance separated quad-alpha waves will have a -1/3 (-1/9 -1/9 -1/9 + 0/9 + 0/9 + 0/9). The total particle charge is +1 (+2/3 + 2/3 -1/3).
The second particle has a negative charge starting position. Thus, it will have an overall -1 charge generated from the same mathematics as the charge of the first particle. |
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