Theory of Infinitely Extended Particles

TL;DR

This paper proposes a model of particles with infinite extension, avoiding infinities in physical theories by describing particles as continuous energy distributions within a generalized field framework.

Contribution

It introduces a new approach integrating infinite-extended particles into general relativity, deriving finite energy and charge distributions, and applying these to fundamental particle mass calculations.

Findings

Derives a finite energy density distribution for particles.

Obtains particle masses consistent with experimental values.

Provides a unified field perspective for elementary particles.

Abstract

The difficulties with which the concept of point-like particles is beset, such as the infinities encountered in the existing theories of elementary particles, suggest a different approach to the study of these particles. Instead of restricting ourselves to the concept of point-like particles, we should extend our investigation to the implication of the concept of particles having infinite extension. Such a particle should consist of a continuous distribution of energy over all space, the energy density tending to zero at infinity. To achieve this aim, we introduce into the theory of general relativity the postulate that the gravitational, electric and nuclear fields are special cases of a more general field. An expression is obtained for the gravitational potential which differs from the usual expression of the potential accepted in general relatvity, and which gives an energy density for the particle at every point of space, the integral of which over all space is equal to the mass of the particle, the greatest part of the mass being concentrated near the center of the spherical pattern constituting the particle. The particle is thus seen to consist of the energy of its field. No infinities are encountered in the integrations. The same result is obtained for a charged particle. The charge density is spread out over all space and the integrals of the charge density and energy density are respectively equal to the charge and mass of the particle. The electric potential this obtained is inserted in Dirac's wave equation, and gives a series of equations of increasing degree, the first of which gives the mass of the muon. When inserted in Dirac's wave equation, this potential gives the values of the masses of baryons. When inserted in the Klein-Gordon equation, this potential gives the values of the masses of mesons.