TFNR - Spin and magnetic phenomena

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Charge and Spin, electric and magnetic phenomena are inextricably linked, as well highlighted by the synthesis that, since the developments in classical physics, we know under the name of the theory of electromagnetism. In short, the variation of the electric field induces a variation of the magnetic field, even in the absence of a conductor, and the inverse, a variation of the magnetic field induces an electric field. Electric field and magnetic field, electric force and magnetic force are closely connected. They seem to share the same origin, mirror laws or in any case intertwined, common phenomena.

Even in our model that is based on the Dynamics of Elementary Action, electric and magnetic phenomena manifest all their connections, starting from the common origin of the dynamics of the Component of Rotation, even if the former are linked to the sub-Mode that we call Chirality, the latter, the magnetic phenomena, are linked to the sub-Mode AxisOrientation. Both are components of the physical quantity "intrinsic angular momentum", intrinsic, i.e. relative to the individual event points of the structured Elementary Field, of the portions that from time to time support the Existence and Essence / Form of the InfoStructures.

It is for this reason that to deal with Spin and magnetic phenomena we will use the same scheme and quite symmetrical contents to those expressed in the previous section relating to Charge and electric phenomena.




It is the state of a space-time domain where the distribution of the stochastic perturbations that constitute the Elementary Action is characterized by orientation of the axis of vorticity.

This is the root of magnetic phenomena.

So, in a space-time domain, as for a particle of matter or for radiation, we can identify rotation / “spin”, or orientation of the axis of Rotation, a particular form of the correlation of the distributions of the elementary perturbations of the point-events that compose that domain (Spin).

See also

Links to the tables of contents of TFNR Paper