The minimum mass of a charged spherically symmetric object in $D$ dimensions, its implications for fundamental particles, and holography

TL;DR

This paper derives bounds on the mass and radius of charged, stable objects in higher-dimensional spacetime, linking general relativity, quantum mechanics, and fundamental particles, with implications for holography and dark energy.

Contribution

It introduces new bounds for mass/radius ratios of charged objects in D dimensions, connecting classical and quantum stability conditions, and applies these to fundamental particles like the electron.

Findings

Reproduces the classical electron radius from general relativity.

Provides bounds on charge/mass ratio consistent with electron properties.

Suggests a link between gravity, dark energy, and particle stability.

Abstract

We obtain bounds for the minimum and maximum mass/radius ratio of a stable, charged, spherically symmetric compact object in a $D$-dimensional space-time in the framework of general relativity, and in the presence of dark energy. The total energy, including the gravitational component, and the stability of objects with minimum mass/radius ratio is also investigated. The minimum energy condition leads to a representation of the mass and radius of the charged objects with minimum mass/radius ratio in terms of the charge and vacuum energy only. As applied to the electron in the four-dimensional case, this procedure allows one to re-obtain the classical electron radius from purely general relativistic considerations. By combining the lower mass bound, in four space-time dimensions, with minimum length uncertainty relations (MLUR) motivated by quantum gravity, we obtain an alternative bound for the maximum charge/mass ratio of a stable, gravitating, charged quantum mechanical object, expressed in terms of fundamental constants. Evaluating this limit numerically, we obtain again the correct order of magnitude value for the charge/mass ratio of the electron, as required by the stability conditions. This suggests that, if the electron were either less massive (with the same charge) or if its charge were any higher (for fixed mass), a combination of electrostatic and dark energy repulsion would destabilize the Compton radius. In other words, the electron would blow itself apart. Our results suggest the existence of a deep connection between gravity, the presence of the cosmological constant, and the stability of fundamental particles.