Experimental Consequences of the Hypothesis About a Fundamental Mass in High - Energy Physics

TL;DR

This paper explores a new quantum field theory incorporating a fundamental mass scale, predicting novel interactions that violate certain symmetries and differ from standard theory at ultra-high energies.

Contribution

It introduces a quantum field theory with a fundamental mass scale and analyzes its implications, including symmetry violations and altered high-energy interactions.

Findings

Novel interactions induced by geometric momentum space structure.

Violations of P and CP symmetries at ultrahigh energies.

Helicity non-preservation in high-energy processes.

Abstract

This work continues earlier investigations towards constructing a consistent new Quantum Field Theory with fundamental mass $M$, defining a hypothetical but universal scale in the region of ultrahigh energies. From a theoretical point of view the fundamental mass $M$ and corresponding to it the fundamental length $\ell =\hbar/Mc$ are supposed to play a major role such as Planck's constant $\hbar$, the speed of light $c$ or Newton's gravitational constant $ \kappa $. The standard Quantum Field Theory is recovered in the flat limit. Furthermore, on the basis of this theory various cross sections of fundamental processes have been calculated. Some results revealed that the novel interaction induced via the geometric structure of the momentum space do not keep spirally. As a characteristic feature this interaction inherently leads to a violations of fundamental symmetries, such as $P$ and $CP$. Also the helicity will no longer be preserved at ultra-high energies.