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7. Matter- sub atomics and atomics
| 7.12 |
The different orbit positions for ergon particles around an atomic nuclei |
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| Considering the understandings of rotaxis and orbit positions from the previous chapters, it should be expected that not all structures that compose an atomic nucleus orbit at the same geometric incline, nor radius from the core structures. This is especially so, when considering the various ergon particles such as magnetons, electron neutrinos, positrons and electrons. | ||
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| 7.12.1 | Specific orbit positions- avoiding collision, unique behaviour | |
| Two key points emerge thanks to unique orbit position- the general avoidance of collision, the unique behaviour of groups of particles in form, and in particle fields. | ||
| In particles such as Magnetons possessing specific orbit positions, internally and as external fields, we can see the effect of large external field impact as well as impact within form. Magnetons via orbit help keep electron and positron fields stable (hence three phase). Photons, attract greater mass (hydrogen). | ||
| In terms of Photons, we see Photon particle fields having a strong attraction for Proton material. Thus, the entry point for the Earth ( being the South Pole, which is actually the true magnetic North pole) we should see gradual periods of build up of essential and basic atomic structures (e.g. H2O) and periods of decline in lower periods of Photon production. This is exactly what has been happening with the gradual increase in the mass if the Antarctic ice pack for around 6000 -6500 years. | ||
| We also see a proof of the theory of different orbit angles for the various ergon particle fields when considering the Earth's magnetic poles shifting over a 12 month period from a maximum distance of around 11 to around 6. | ||
| 7.12.2 | The compression of Atomic cores | |
| In considering orbit position, nature of particle and the effects on size ( as listed in Chapter 6), we should expect to see those atomic cores with greater density to actually be smaller. | ||
| The position of the orbiting ergons within the core and external to the core act as a kind of self tolerance system, providing stability and 3D cohesion. They also help compress the core into a smaller space, thereby increasing the density of the nuclei. | ||
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