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7. Matter- sub atomics and atomics
| 7.10 |
The clues as to how the families of sub-atomic structures form atomic structures |
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| Most first year chemistry students have seen the practical example of Magnesium atoms burning on contact with the air. There is also strong inferred evidence of the relative abundance of different atomic structures such as Hydrogen compared to Carbon. We also have the years of research weighing and determining the relative characteristics of various atomic structures such as Uranium and Iron. | ||
| Let us look at that these clues provide us as an understanding of the laws that dictate the "can do" and "cannot do" processes of forming atomic structures. | ||
| In the English language, there are literally millions of words, categorized into thousands of relationships and patterns. | ||
| 7.10.1 | The rules of density/pressure/levels of kinesis to form more complex shapes | |
| Firstly, for strong nuclear fusion to occur, we require the levels of pressure to increase the density of these particles to such a point that the level of kinesis of each structure are at their maximum. At that point, the motion of particles decrease to sufficiently slow rates of motion to allow the rules of Orbit to create form to take place. | ||
| Stars are suitable large, with suitably dense inner cores for this process to take place. In addition the other environments where this takes place in nature are nebulae clouds, supernova and the edge of the Universe where new matter is being created constantly. | ||
| 7.10.2 | The rules of orbit to create form | |
| For core strong fusion, the ratio of like spin attraction must be 1:1 For orbit strong fusion, the ratio of like spin attraction must be 2:1 or greater For weak fusion, the ratio of like spin attraction must be at least greater than 1:1. | ||
| 7.10.3 | The weakening of attraction via orbits | |
| We also know that the effect of orbits is to halve the 1 unit attraction of a creator Unita to another creator particle. For each successive orbit outside form, the attraction/repulsion rate is halved again, and so on. Conversely, we know that in strong core fusion when two like spin particles fuse a core nucleus, their spin attraction is intact. | ||
| 7.10.4 | Strength of like spin multiplied by mass gives us a particles relative attraction | |
| To determine what are the most "attractive" particles, we know attraction is based on the total number of creator Unita minus the total number of destructive attractors, after taking into account orbits, multiplied by the total number of Unita particles. Therefore the Proton is the most "attractive" atomic nuclei particle, followed by the Neutron, the Positron and finally the Electron. | ||
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