The Dirac Electron and Elementary Interactions: The Gyromagnetic Factor, Fine-Structure Constant, and Gravitational Invariant: Deviations from Whole Numbers

Conference paper
Part of the Progress in Theoretical Chemistry and Physics book series (PTCP, volume 31)

Abstract

In previous papers, we revisited the Dirac equation and conjectured that the electron can be viewed as a massless charge spinning at light speed, this internal motion being responsible for the rest mass involved in external motions and interactions. Implications of this concept on basic properties such as time, space, electric charge, and magnetic moment were considered. The present paper investigates the deviations of the resulting gyromagnetic factor, fine-structure constant, and gravitational invariant from their integer approximates, and their implication in a better understanding of the electromagnetic, gravitational, and other interactions.

Keywords

Dirac equation Spin momentum Magnetic moment Matter antimatter Wave beat Zitterbewegung Light velocity Compton diameter Planck units Catalan numbers Casimir force Nuclear forces Gyromagnetic factor Fine-structure constant Gravitational invariant Quantum electrodynamics General relativity 

Notes

Acknowledgements

I wish to thank the colleagues who helped me clarify these ideas at QSCP meetings and elsewhere. Erkki Brändas, Uzi Kaldor, John Macken, Francis Sanchez, and Ivan Todorov made especially useful comments. Thanks are due to my wife, Marja Rantanen, for stimulating my speculations with inspiring piano playing.

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Copyright information

© Springer International Publishing AG, part of Springer Nature 2018

Authors and Affiliations

  1. 1.Laboratoire de Chimie Physique-Matière et RayonnementCNRS & UPMCParisFrance

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