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An Electromagnetic Resonance Based Interpretation of Quantum Theory
American Journal of Modern Physics
Volume 4, Issue 3, May 2015, Pages: 125-131
Received: Mar. 30, 2015; Accepted: Apr. 9, 2015; Published: May 15, 2015
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Author
Thomas A. Kriz, Alpha Omega Advanced Studies, Cedar Park, USA
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Abstract
An electromagnetic (EM) resonance based model derived from Maxwell's Equations is used with constraint conditions to characterize the quantum properties of both matter particles and photons. The model, as constrained by integer spin-orbit ratio, integer multiples of Planck's constant, angular momentum balance, charge balance, and EM resonance form, yields analytical results that are comparable to those from traditional quantum mechanics (QM), and electrodynamics (QED), but obtained with reduced analytical effort. EM compound resonance models are used to characterize quantum chromodymanics (QCD) quarks in neutrons and protons. It is also shown that EM resonance models give evidence that supports QCD “color-confinement” and “color-change” concepts. Analysis is limited to steady-state resonance forms.
Keywords
Maxwell's Equations, Electromagnetic Resonance, Quantum Mechanics, Quantum Electrodynamics, Quantum Chromodynamics
To cite this article
Thomas A. Kriz, An Electromagnetic Resonance Based Interpretation of Quantum Theory, American Journal of Modern Physics. Vol. 4, No. 3, 2015, pp. 125-131. doi: 10.11648/j.ajmp.20150403.14
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