Implications for the hierarchy problem, inflation and geodesic motion from fiber fabric of spacetime

TL;DR

This paper proposes a fiber fabric model of spacetime to address the hierarchy problem, inflation, and geodesic motion, providing a unified framework with predictions consistent with current experiments.

Contribution

It introduces a fiber fabric of spacetime that naturally resolves hierarchy, chirality, and stabilization issues, and develops an inflationary model within this framework.

Findings

Hierarchy problem addressed with TeV-scale parameters

Inflationary observables match current experimental data

Modified geodesic predictions align with observational constraints

Abstract

In this paper, we represent a resolution for the hierarchy problem where the inverse size of the extra dimension and the fundamental Planck scale would all be of the order of the TeV scale by proposing a fiber fabric of spacetime. The origin of the large hierarchy is essentially due to the $\cosh$ function which has a physical origin from the dynamics of the horizontal metric in the vacuum of non-zero energy. In addition, the fiber fabric of spacetime allows us to resolve elegantly and naturally the problems of the chirality fermions and stabilizing potential for the size of the extra dimension, which are usually encountered in the higher dimensional theories. Then, we explore the inflation with the modulus of the extra dimension identified as the inflaton where our slow-roll inflationary model belongs to the E-model class with $n=1$. We calculate the main inflationary observables which are consistent with the present experiments. Finally, we study how the geodesic motion of neutral test particles gets modified from the extension of spacetime. We compute the radius of the photon sphere, the innermost stable circular orbit, the perihelion shift, the light bending angle, and the observables of the strong gravitational lensing and the retrolensing phenomenon. By comparing the predicted values with the experimental observations, we determine the constraints on the fiber fabric of spacetime.