The Unipolar Faraday Generator Revisited: Difference between revisions
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When a charge moves, an electromagnetic field surrounding it appears. This field interacts with circuits, resulting in electromotive and ponderomotive phenomena. When a charge is at rest, the field reduces to the Coulomb field; the magnetic part of the Lorentz force '''F '''= <em>q</em>u X '''B '''is absent and neither pondero- nor electro-motive forces appear, <em>no matter how magnets and circuits move.</em> It is shown that neither absolute space nor STR are necessary to explain unipolar induction effect.[[Category:Scientific Paper]] | When a charge moves, an electromagnetic field surrounding it appears. This field interacts with circuits, resulting in electromotive and ponderomotive phenomena. When a charge is at rest, the field reduces to the Coulomb field; the magnetic part of the Lorentz force '''F '''= <em>q</em>u X '''B '''is absent and neither pondero- nor electro-motive forces appear, <em>no matter how magnets and circuits move.</em> It is shown that neither absolute space nor STR are necessary to explain unipolar induction effect. | ||
[[Category:Scientific Paper|unipolar faraday generator revisited]] | |||
Latest revision as of 13:30, 1 January 2017
| Scientific Paper | |
|---|---|
| Title | The Unipolar Faraday Generator Revisited |
| Author(s) | Jorge A Guala-Valverde, Pedro Mazzoni |
| Keywords | Unipolar Faraday Generator, electromagnetic field, Coulomb field, Lorentz force |
| Published | 1993 |
| Journal | Galilean Electrodynamics |
| Volume | 4 |
| Number | 6 |
| Pages | 107-108 |
Abstract
When a charge moves, an electromagnetic field surrounding it appears. This field interacts with circuits, resulting in electromotive and ponderomotive phenomena. When a charge is at rest, the field reduces to the Coulomb field; the magnetic part of the Lorentz force F = qu X B is absent and neither pondero- nor electro-motive forces appear, no matter how magnets and circuits move. It is shown that neither absolute space nor STR are necessary to explain unipolar induction effect.