Binding Energies of the Alpha Particle and the A=3 Isobars from a Theoretical Geometric Model

TL;DR

This paper introduces a geometric model of nuclear electromagnetism to theoretically calculate the binding energies of the alpha particle and A=3 isobars, providing results close to experimental values.

Contribution

It proposes a novel triple geometric structure for nuclear electromagnetic interactions to compute binding energies of light nuclei.

Findings

Calculated binding energies: 28.5 MeV (alpha particle), 7.64 MeV (helium-3), 8.42 MeV (tritium).

Model establishes proton-electron-proton magnetic bonds in these nuclides.

Results suggest the model's potential for accurate nuclear energy predictions.

Abstract

We assume a triple geometric structure for the electromagnetic nuclear interaction. This nuclear electromagnetism is used to calculate the binding energies of the alpha particle and the A=3 isobar nuclides. The approximation for the resultant wave equation which lead to the deuteron binding energy from the modified Mathieu equation for the radial eigenvalue equation also establishes proton-electron-proton magnetic bonds in these nuclides and determines their binding energies. Completely theoretical calculations give 28.5 Mev., 7.64 Mev. and 8.42 Mev. for the binding energies of the alpha particle, the helium 3 isotope and tritium respectively. These values admit correction factors due to the approximations made.