Theory on Temperature and Loose Electron Orbitals

When electrons are too far away, or incapable of bonding to their proton partner, they still remain attracted to the proton, and inversely to its poles. This loose bonding means that the proton’s attraction is not one on one with the electron, instead it acts as a positive field area for the electron to be attracted to. The electron, respectively becomes held in this area, loosely, and because of nearby neutrons and other electron orbitals, its shape of influence alters. The closer the electron is to the proton, the more inverse its poles will be. Thus the electron will veer to electron orbitals in the area that are inverse to it, but will be repulsed by electrons in the area that are not inverse to it.

I will post pictures explaining this later.

I have also been working on the theory that electron orbitals determine energy absorption and dissipation, and that it is the way in which the orbitals react with the quanta fields that determine if an atom is a gas or solid or metal.

If I can discover the inner structure of Boron and Carbon, I think I can build upon that to discover why some atoms behave as gasses at room temperature and why some behave as a solid. Remember, as you well know, that the reason things are metals, solids, and gasses, at room temperature is because they are that way at room temperature. Temperature is simply a matter of energy levels of a given state. And since energy is the exchange of quanta in atomic quanta fields and mainly through electrons, the temperature will determine how they react to each other.

The more quanta in the area the more chances for reactions of attraction and repelling. This is heating, or increasing the temperature. Thus not only does this cause stress upon the quanta fields, this stresses electron orbitals and changes how well they attract or repel each other. The more energy in the system, the more quanta. This increases quanta field strength and size. While it may add chaos in some areas, the field strengths increase stability, but the stronger the fields in magnets, the smaller the size of the initial area of attraction. The orbitals may actually all shrink, thus repelling each other until the atoms, as energy is added, become a gas, then finally a form of plasma, the result is that the atoms act like inert objects that become more like electron charges than actual particles.

When you take away quanta, or energy, from the quanta fields electrons and their orbitals, which is what decreasing the temperature does, you cause the quanta fields to lose strength, they expand a bit in certain directions, and their attraction is weaker, but at the same time, more felt, for the attraction area is increased because the fields are less compressed.

So now we have very strong attraction fields because the window of attraction is open wider, and it is easy for the electron orbitals to form more solid bonds with other atoms, and they tend to crystallize, as their bonds are very strong.

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