As told already, an electron's spin works to determine its magnetic field. This is because the magnetic field of an electron is normal to its electric field, and an electric field is based on the angular momentum of the given electron. Angular momentum is based on the directoral impetus of the electron in any series of locants, as implied before. In order for something to spin, the phenomenon has to go around. That's what spinning is. This means that the surface area of any object that spins must have radial translation after every discrete metric in which that object does indeed spin. Whenever something exists, it exists in some sort of space. Anything that exists in space is touching something, and at every spot in which it exists. Whenever there is touch, there is tangency. So, everything that exists involves tangency. The condition of tangency is normalcy. This is because wherever there's a tangency point, there is a norm vector. So, anything that exists has some sort of normalcy that is associated with whatever topological surface that you may wish to discuss. Normalcy may not always be associated with Real space, yet it is always associated with some sort of medium through which points or indices may be relayed or at least temporarily transferred. whenever radial motion happens, there is always at least a potential of spinning of either the object in radial motion or the indices that it translocates. Radial motion that differentiates homotopically through a metric always involves actual spinning. Let's say that you are a small point. You are on the surface of a smooth paraboloid. The paraboloid spins. Remember, you are touching the paraboloid. As the paraboloid spins, you spin with it. You are staying put on the relative spot of the paraboloid, now. So, you are in tact with a constantly differentiating norm vector that is kept in the sequential pattern of the spinning of the paraboloid. I will continue with the suspense of this session later. Until then, I hope that you are having a phenomenal day.
Catch you two!
Sincerely,
Samuel
Catch you two!
Sincerely,
Samuel
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