Difference between revisions of "Amp?re vs. Grassmann on Experimental Grounds"
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− | The growing interest in a thorough revision of the tenets of classical electrodynamics compels the physics community to reconsider the dominating magnetic field rationale applied to electrodynamics since the time of Lorentz. The torque-production mechanism presently attributed to homopolar machines, which is based on Grassmann's force, has been definitively ruled out by recent crucial experimentation. Conversely, Ampere's force law, restating the Newtonian symmetry requirement for energy conversion, fully explains homopolar torque production.[[Category:Scientific Paper]] | + | The growing interest in a thorough revision of the tenets of classical electrodynamics compels the physics community to reconsider the dominating magnetic field rationale applied to electrodynamics since the time of Lorentz. The torque-production mechanism presently attributed to homopolar machines, which is based on Grassmann's force, has been definitively ruled out by recent crucial experimentation. Conversely, Ampere's force law, restating the Newtonian symmetry requirement for energy conversion, fully explains homopolar torque production. |
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+ | [[Category:Scientific Paper|amp vs grassmann experimental grounds]] | ||
[[Category:Electrodynamics]] | [[Category:Electrodynamics]] |
Revision as of 09:57, 1 January 2017
Scientific Paper | |
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Title | Amp?re vs. Grassmann on Experimental Grounds |
Author(s) | Jorge A Guala-Valverde, Ricardo A Achilles |
Keywords | {{{keywords}}} |
Published | 2010 |
Journal | Galilean Electrodynamics |
Volume | 21 |
Number | 1 |
Pages | 18-21 |
Abstract
The growing interest in a thorough revision of the tenets of classical electrodynamics compels the physics community to reconsider the dominating magnetic field rationale applied to electrodynamics since the time of Lorentz. The torque-production mechanism presently attributed to homopolar machines, which is based on Grassmann's force, has been definitively ruled out by recent crucial experimentation. Conversely, Ampere's force law, restating the Newtonian symmetry requirement for energy conversion, fully explains homopolar torque production.