Difference between revisions of "Wave Solution of Generalized Maxwell Equations and Quantum Mechanics ? Part I"
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A wave version for generalized Maxwell equations is proposed. The wave created by a moving electron is described on the basis of a torus model proposed earlier in a paper devoted to a Maxwell approach to gravity. This wave is described by torsion oscillations. A corresponding vortex carries mass. Therefore, moving electrons and photons possess qualities as both waves and particles. Conformity of the derived results with experiments underlying quantum mechanics is verified. A fact that staggered the author was found: the electron creates a time-independent standing wave that defines the Coulomb force. In particular, this means that the Coulomb force is a long-range one. | A wave version for generalized Maxwell equations is proposed. The wave created by a moving electron is described on the basis of a torus model proposed earlier in a paper devoted to a Maxwell approach to gravity. This wave is described by torsion oscillations. A corresponding vortex carries mass. Therefore, moving electrons and photons possess qualities as both waves and particles. Conformity of the derived results with experiments underlying quantum mechanics is verified. A fact that staggered the author was found: the electron creates a time-independent standing wave that defines the Coulomb force. In particular, this means that the Coulomb force is a long-range one. | ||
− | [[Category:Scientific Paper]] | + | [[Category:Scientific Paper|wave solution generalized maxwell equations quantum mechanics]] |
[[Category:Gravity]] | [[Category:Gravity]] |
Revision as of 11:38, 1 January 2017
Scientific Paper | |
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Title | Wave Solution of Generalized Maxwell Equations and Quantum Mechanics ? Part I |
Author(s) | Jaroslav G Klyushin |
Keywords | {{{keywords}}} |
Published | 2004 |
Journal | Galilean Electrodynamics |
Volume | 15 |
Number | S2 |
Pages | 30-34 |
Abstract
A wave version for generalized Maxwell equations is proposed. The wave created by a moving electron is described on the basis of a torus model proposed earlier in a paper devoted to a Maxwell approach to gravity. This wave is described by torsion oscillations. A corresponding vortex carries mass. Therefore, moving electrons and photons possess qualities as both waves and particles. Conformity of the derived results with experiments underlying quantum mechanics is verified. A fact that staggered the author was found: the electron creates a time-independent standing wave that defines the Coulomb force. In particular, this means that the Coulomb force is a long-range one.