Electrostatic-gravitational oscillator

TL;DR

This paper explores a relativistic model where gravitational attraction can balance electrostatic repulsion between particles, leading to stable oscillatory states and potential explanations for hadron confinement.

Contribution

It introduces a novel relativistic framework showing gravity's role in particle confinement and derives fundamental constants from particle properties.

Findings

Stable oscillatory states for particles with rest mass ~0.4 eV/c2.

Gravity can confine light neutral particles or pairs in tiny circular orbits.

Expresses gravitational constant in terms of fundamental constants.

Abstract

We examine the one-dimensional motion of two similarly charged particles under the influence of only two forces, i.e. their Coulombic repulsion and their gravitational attraction, using the relativistic equation of motion. We find that when the rest mass of the two particles is sufficiently small (~ 0.4 eV/c2) and the initial Coulombic potential energy is sufficiently high (~ mpc2, where mp is the proton mass), then the strong gravitational attraction resulting from the relativistic particle velocities suffices to counterbalance the Coulombic repulsion and to cause stable periodic motion of the two particles. The creation of this confined oscillatory state, with a rest mass equal to that of a proton, is shown to be consistent with quantum mechanics by examining the particle de Broglie wavelength and the Klein-Gordon and Schrodinger equations. It is shown that the gravitational constant can be expressed in terms of the proton mass and charge, the vacuum dielectric constant, the Planck constant and the speed of light. It is also shown that gravity can cause confinement of light (~ 0.1 eV/c2) neutral particles (neutrinos), or pairs of a neutral and a charged light particle, in circular orbits of size 0.9 fm and period 10-24 s forming bound neutral or charged hadron states.