Tag: magnetism.

Discussion of the merits of Gill’s electronic theory of magnetism (1964) over Maxwell’s dipole theory of magnetism (1873) in Chapter 1. The asymmetry problem is resolved and Faraday’s iron ring experiment from 1831 is once again explained. The cross-products of Henrik Lorentz 1893 are not necessary for any computations;...

 Why should ‘Gill’s electronic theory of magnetism 1964’ and its dot product equations be used instead of ‘Maxwell’s dipole theory of magnetism 1873’ and its cross-product equations? With the help of ‘Gill’s electronic theory of magnetism 1964,’ the following topics linked to Maxwell’s equations will be revisited and explained:...

It will be mathematically explained how objects close to the Earth fall towards the Earth with a combination of these two forces by applying Gill’s electronic theory of magnetism 1964 to planet Earth and relating it to the electron dependant negative force (-e) and the proton dependant positive force...

A diagrammatic and experimental representation of Gill’s electronic theory of magnetism 1964 illustrates that a magnet has a negative or north magnetic pole N and a positive or south magnetic pole S. Because of the direction of a magnetic compass on the magnetic Earth’s surface, these magnetic poles are...

The property of matter is characterised by mass expressing its measure of inertia, and energy is in equilibrium with the environment-the measure of motion and structural-energy c correspondence in the system. Violation by external interference of this stationary state of the system triggers the occurrence of physical and chemical...