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Electromagnetic fields on a quantum scale. I.

Dale M Grimes1, Craig A Grimes

  • 1Department of Electrical Engineering, Pennsylvania State University, University Park, Pennsylvania, USA.

Journal of Nanoscience and Nanotechnology
|August 12, 2003
PubMed
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This study models quantum theory using classical electromagnetism, revealing electron non-locality and standing electromagnetic energy. These properties explain wave function statistics, atomic stability, and causality in quantum mechanics.

Area of Science:

  • Quantum mechanics
  • Classical electro-magnetism
  • Atomic physics

Background:

  • The statistical nature of quantum theory remains incompletely explained.
  • Established quantum mechanics interpretation predates key discoveries like electron non-locality.

Purpose of the Study:

  • To present a model-based, hidden variable analysis of quantum theory.
  • To provide a physical basis for the statistical nature of wave functions.
  • To reconcile classical electro-magnetism with quantum phenomena.

Main Methods:

  • Utilizing classical electro-magnetism and conservation of energy equations.
  • Modeling the eigenstate electron as a nonlocal entity.
  • Analyzing the effects of standing electromagnetic energy and radiation reaction forces.

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Main Results:

  • Demonstrated that electron non-locality and standing electromagnetic energy are key to quantum theory.
  • Showed these properties provide a basis for the Schrödinger equation.
  • Derived the uncertainty and exclusion principles from the model.
  • Established atomic stability and causality.

Conclusions:

  • A hidden variable analysis using classical electro-magnetism can explain quantum phenomena.
  • Electron non-locality and standing electromagnetic energy are fundamental properties.
  • This model offers a new perspective on wave function statistics and atomic behavior.