Fiber bundle description of number scaling in gauge theory and geometry

TL;DR

This paper employs fiber bundles to model number scaling effects in gauge theory and geometry, revealing how scalar fields influence vector and geometric structures, with implications for massless and massive gauge bosons.

Contribution

It introduces a fiber bundle framework incorporating number scaling into gauge theory and geometry, providing new insights into the behavior of gauge fields and geometric quantities.

Findings

B field is massless and unaffected by electromagnetic fields.

The A field influences path lengths and geodesics.

Lack of evidence for the gradient field suggests weak coupling or near-zero values.

Abstract

This work uses fiber bundles as a framework to describe some effects of number scaling on gauge theory and some geometric quantities. A description of number scaling and fiber bundles over a flat space time manifold, M, is followed by a description of gauge theory. A fiber at point x of M contains a pair of scaled complex number and vector space structures, $C^{c}_{x}\times V^{c}_{x} $ for each c in GL(1,C). A space time dependent scalar field, g, determines, for each x, the scaling value of the vector space structures that contain the values of a vector valued matter field at x. The vertical components of connections between neighboring fibers are taken to be the gradient field A(x)+iB(x), of g. Abelian gauge theory for these fields gives the result that B is massless and no mass restrictions for A. Addition of an electromagnetic field dies not change these results. In the Mexican hat Higgs mechanism B combines with a Goldstone boson to create massive vector bosons, the photon field, and the Higgs field. For geometric quantities the fiber bundle is a tangent bundle with a fiber at point x containing scaled pairs, $R^{r}_{x}\times T^{r}_{x}$ of real number and tangent space structures for each x and and nonnegative real r. B is zero everywhere. The A field affects path lengths and the proper times of clocks along paths. It also appears in the geodesic equation. The lack of physical evidence for the gradient field, A(x)+iB(x) means that it either couples very weakly to matter fields or that it is close to zero for all x in a local region of cosmological space and time. It says nothing about the values outside the local region.