What is it about?
Exploring the unknown so far, possible intrinsic inner mechanics of the "mysterious" electron by quantum emulation experiment, simulations and 4D mathematical animations and extrapolating a fiber model of the electron at rest that predicts all of its intrinsic known measured values like charge, magnetic moment, angular momentum etc.
Featured Image
Photo by Compare Fibre on Unsplash
Why is it important?
From physical quantum emulation observations, mathematical analysis and Wolfram Alpha parametric polar simulations and mathematical 4D animations we calculated a fiber model for the dressed bare mass electromagnetic field of the electron that results to all of its known measured intrinsic properties like charge, angular momentum, magnetic dipole moment, handedness etc. Therefore our model is an intrinsic mechanics model for the electron at rest and shows the possibility that the elementary electron although it has no inner sub-particles, it can posses a specific energy flux manifold. Therefore our novel fiber model opens up a new door on theoretical intrinsic mechanics physics of elementary particles beyond the Standard Model. Research Highlights • Novel fiber model for the electron at rest calculating all of its intrinsic properties like charge, angular momentum, spin, magnetic dipole moment, handedness etc. • Fiber model shows the possibility of electron having intrinsic mechanics in the form of a specific energy flux manifold. • Electron described as ½ spin dynamic topology twisted photon. • The unified electromagnetic flux field manifold of the electron at rest is shown and the origin of the fine structure constant as a proportionality constant of the electron topology. • Model was extrapolated by physical quantum emulation, analytically verified and also algorithmically using Wolfram Alpha parametric polar simulations.
Perspectives
Read the Original
This page is a summary of: A ½ spin fiber model for the electron, International Journal of Physical Research, January 2022, Science Publishing Corporation,
DOI: 10.14419/ijpr.v10i1.31874.
You can read the full text:
Resources
Open Access Article on SSRN repository
Alternative URL location for the Open Access Published Article PDF.
Animation page of the animations used inside the Article and the research.
Mathematical animations created for the fiber model for the electron and research.
Supplementary material of paper on Google Drive
Research supplementary material and datasets.
Contributors
The following have contributed to this page