Magnetostatics at Speed c: Difference between revisions
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Three separate subject areas are discussed. In the first, several experiments are described concerning the nature of light and the electromagnetic field. Three of them cannot be explained by either classical or quantum theory, thus demonstrating that a more comprehensive theory of electromagnetic radiation is needed. Next, some theoretical requirements are enumerated that must be satisfied if the concept of "photon" is to be employed in formulating a theory that can be considered complete. In the last section field diagrams are used to show that theory and experiment may be reconciled by conceiving of photons as localized concentrations of magnetic field.[[Category:Scientific Paper]] | Three separate subject areas are discussed. In the first, several experiments are described concerning the nature of light and the electromagnetic field. Three of them cannot be explained by either classical or quantum theory, thus demonstrating that a more comprehensive theory of electromagnetic radiation is needed. Next, some theoretical requirements are enumerated that must be satisfied if the concept of "photon" is to be employed in formulating a theory that can be considered complete. In the last section field diagrams are used to show that theory and experiment may be reconciled by conceiving of photons as localized concentrations of magnetic field. | ||
[[Category:Scientific Paper|magnetostatics speed c]] | |||
Latest revision as of 12:39, 1 January 2017
| Scientific Paper | |
|---|---|
| Title | Magnetostatics at Speed c |
| Read in full | Link to paper |
| Author(s) | Richard Oldani |
| Keywords | Magnetostatics, Speed of Light, c |
| Published | 2000 |
| Journal | None |
| No. of pages | 7 |
Read the full paper here
Abstract
Three separate subject areas are discussed. In the first, several experiments are described concerning the nature of light and the electromagnetic field. Three of them cannot be explained by either classical or quantum theory, thus demonstrating that a more comprehensive theory of electromagnetic radiation is needed. Next, some theoretical requirements are enumerated that must be satisfied if the concept of "photon" is to be employed in formulating a theory that can be considered complete. In the last section field diagrams are used to show that theory and experiment may be reconciled by conceiving of photons as localized concentrations of magnetic field.