Identification and acceptation of macroscopic magnetism energy levels results in better understanding of the linkages between the traditional theory with quantum electrodynamics and revelation of the limited validity of the Faraday's Law

TL;DR

This paper explores macroscopic magnetic energy levels and their implications for electrodynamics, challenging traditional theories and suggesting a broader, topological understanding of magnetic induction that refines Faraday's Law.

Contribution

It introduces the concept of magnetic energy levels as a macroscopic manifestation and proposes a topological evaluation of magnetic induction, extending classical electrodynamics.

Findings

Magnetic energy levels are measurable and may be a macroscopic effect.

Current electrodynamics simplifies the magnetic induction vector.

Refined understanding narrows Faraday's Law and enhances predictive accuracy.

Abstract

In this article, we present the result of the research, which was directed to gaining electromotive voltage in a theoretically pure way. We designed and built a brushless generator that simulates a homogenised magnetic field and should theoretically be usable without semiconductors and electronic components. The generator is equipped with superconductive shielding, which ensures the disruption of the theoretical balance of electromotive voltage generation. In the Faraday homopolar generator, the imbalance of the electromotive voltage is secured by fixing the disk to the reference set of rotating magnets. However, the solution of the technical problem initiated a theoretical problem. The result of the experiment suggests that the current concept of electrodynamics, based on magnetic flux using relativistic principles, is Euclidean, idealised. If we continue to persist in the unconditional correctness of Maxwell's concept, we would have to admit that the inhomogeneous field can be screened out of the perspective of any external reference system, but that for a homogeneous magnetic field such a reference system would not exist. A good explanation of the inconsistency with theoretical expectations gives us the introduction of energy levels of the magnetic field, which are measurable and are probably a macroscopic manifestation of the summation of levels from elementary particle environments. Part of this article is an analysis which shows that current electrodynamics use a simplified view of the vector of induction. We show that the induction is a special case of a more general, topological evaluation of the properties of the set of magnetic field vectors. This unavoidably leads to a narrowing of Faraday's Law, which improves the experimental prediction and paradoxically reveals considerable technical potential. Both concepts can coexist in practice, with a wide range of value matches.