Difference between revisions of "Superluminal Interaction, or The Same, de Broglie Relationship, As Imposed By The Law of Energy Conservation. Part I: Electrically Bound Particles"
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<span lang="EN-US" style="FONT-SIZE: 10pt"><span style="FONT-FAMILY: Times New Roman">Based on the law of energy conservation, we figured out that, the steady state electronic motion around a given nucleus generally depicts a rest mass variation throughout, though the overall relativistic energy remains constant. Note that our approach is, in no way, conflicting with the usual quantum mechanical approach. Quite on the contrary it provides us with the possibility of elucidating the ?quantum mechanical weirdness?. We happened to develop our theory originally vis-?-vis gravitational bodies in motion with regards to each other; hence, it is comforting to have both the atomic scale and the celestial scale described on just the same conceptual basis.<span style="mso-spacerun: yes"> </span>One way to conceive the phenomenon we disclosed is to consider a ''?jet effect?.'' Accordingly, a particle on a given orbit through its journey must eject a net mass from its back to accelerate, or must pile up a net mass from its front to decelerate, while its overall relativistic energy stays constant throughout. The speed of the jet, strikingly, points to the de Broglie wavelength</span><span style="FONT-FAMILY: Times New Roman">, coupled with the </span><span style="FONT-FAMILY: Times New Roman">inverse of the frequency,</span><span style="FONT-FAMILY: Times New Roman"> delineated by the electromagnetic energy content </span><span style="FONT-FAMILY: Times New Roman">of the object of concern.</span><span style="FONT-FAMILY: Times New Roman">This makes that, on the whole, the ''jet speed'' becomes a ''superluminal speed''</span><span style="FONT-FAMILY: Times New Roman">, yet excluding any transport of energy. Recent measurements appear to back up our conjecture. Here, furthermore may be a clue, for the ''wave-particle duality. <p> </p>''</span></span> | <span lang="EN-US" style="FONT-SIZE: 10pt"><span style="FONT-FAMILY: Times New Roman">Based on the law of energy conservation, we figured out that, the steady state electronic motion around a given nucleus generally depicts a rest mass variation throughout, though the overall relativistic energy remains constant. Note that our approach is, in no way, conflicting with the usual quantum mechanical approach. Quite on the contrary it provides us with the possibility of elucidating the ?quantum mechanical weirdness?. We happened to develop our theory originally vis-?-vis gravitational bodies in motion with regards to each other; hence, it is comforting to have both the atomic scale and the celestial scale described on just the same conceptual basis.<span style="mso-spacerun: yes"> </span>One way to conceive the phenomenon we disclosed is to consider a ''?jet effect?.'' Accordingly, a particle on a given orbit through its journey must eject a net mass from its back to accelerate, or must pile up a net mass from its front to decelerate, while its overall relativistic energy stays constant throughout. The speed of the jet, strikingly, points to the de Broglie wavelength</span><span style="FONT-FAMILY: Times New Roman">, coupled with the </span><span style="FONT-FAMILY: Times New Roman">inverse of the frequency,</span><span style="FONT-FAMILY: Times New Roman"> delineated by the electromagnetic energy content </span><span style="FONT-FAMILY: Times New Roman">of the object of concern.</span><span style="FONT-FAMILY: Times New Roman">This makes that, on the whole, the ''jet speed'' becomes a ''superluminal speed''</span><span style="FONT-FAMILY: Times New Roman">, yet excluding any transport of energy. Recent measurements appear to back up our conjecture. Here, furthermore may be a clue, for the ''wave-particle duality. <p> </p>''</span></span> | ||
− | [[Category:Scientific Paper]] | + | [[Category:Scientific Paper|superluminal interaction broglie relationship imposed law energy conservation electrically bound particles]] |
− | [[Category:Relativity]] | + | [[Category:Relativity|superluminal interaction broglie relationship imposed law energy conservation electrically bound particles]] |
Latest revision as of 19:57, 1 January 2017
Scientific Paper | |
---|---|
Title |
Superluminal Interaction, or The Same, de Broglie Relationship, As Imposed By The Law of Energy Conservation. Part I: Electrically Bound Particles |
Read in full | Link to paper |
Author(s) | Tolga Yarman |
Keywords | Special Theory of Relativity, Electric Interaction, Tachyons, Superluminal Interaction, General Theory of Relativity, Gravitation |
Published | 2008 |
Journal | None |
No. of pages | 42 |
Read the full paper here
Abstract
Based on the law of energy conservation, we figured out that, the steady state electronic motion around a given nucleus generally depicts a rest mass variation throughout, though the overall relativistic energy remains constant. Note that our approach is, in no way, conflicting with the usual quantum mechanical approach. Quite on the contrary it provides us with the possibility of elucidating the ?quantum mechanical weirdness?. We happened to develop our theory originally vis-?-vis gravitational bodies in motion with regards to each other; hence, it is comforting to have both the atomic scale and the celestial scale described on just the same conceptual basis. One way to conceive the phenomenon we disclosed is to consider a ?jet effect?. Accordingly, a particle on a given orbit through its journey must eject a net mass from its back to accelerate, or must pile up a net mass from its front to decelerate, while its overall relativistic energy stays constant throughout. The speed of the jet, strikingly, points to the de Broglie wavelength, coupled with the inverse of the frequency, delineated by the electromagnetic energy content of the object of concern.This makes that, on the whole, the jet speed becomes a superluminal speed, yet excluding any transport of energy. Recent measurements appear to back up our conjecture. Here, furthermore may be a clue, for the wave-particle duality.