Abstract
The origin for one of the fundamental laws of electromagnetism, namely Faraday’s law is explained for the first time on the basis of the presence of strings in the form of a compact liquid. The rate of change of the magnetic field produces a pressure gradient in the medium giving rise to the fluid flow. According to fluid dynamics, the stress and the gradient of strain are originated in the space which creates vibrations in the system and is related with the electric field. The details of the mechanism which produces a circular motion of the electric field, XE, are also addressed.
Highlights
Faraday’s law of induction is one of the basic principles of electromagnetism which shows that the change in the magnetic field produces an electric field
An important aspect of the present theory is that the change in the density of the magnetic field in the space gives rise to the electric field
The magnitude of the stress tensor varies in the space from point to point according to the intensity of the magnetic field and a strain gradient is created which has important consequences in the fluid dynamics
Summary
Faraday’s law of induction is one of the basic principles of electromagnetism which shows that the change in the magnetic field produces an electric field. In spite of its importance in the field of electromagnetism and its applications in modern technology, the origin for this phenomenon is not known. It has never been discussed how and why the variation in the magnetic field gives rise to the electric field in the form of rotational energy. This most significant principle needs to be examined in order to understand the mechanism behind it. An important aspect of the present theory is that the change in the density of the magnetic field in the space gives rise to the electric field. The change in the magnetic field, dB , in an incompressible fluid creates dt several significant alterations in the fluid
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