Lifting Spacetime's Poincar\'e Symmetries

TL;DR

This paper introduces a 5-vector theory that elevates scalar field theory to a Poincaré-invariant framework by lifting symmetries and reformulating spacetime data as matter field data, with implications for discrete spacetime models.

Contribution

It develops a novel 5-vector field approach and a new unfied vierbein structure to reinterpret Poincaré symmetries in scalar field theory, bridging continuous and discrete spacetime.

Findings

Formulation of a non-unitary Poincaré group representation

Introduction of a 5x5 unfied f"unfbein structure

Reinterpretation of spacetime data as matter field data

Abstract

In the following work, we pedagogically develop 5-vector theory, an evolution of scalar field theory that provides a stepping stone toward a Poincar\'e-invariant lattice gauge theory. Defining a continuous flat background via the four-dimensional Cartesian coordinates $\{x^a\}$, we `lift' the generators of the Poincar\'e group so that they transform only the fields existing upon $\{x^a\}$, and do not transform the background $\{x^a\}$ itself. To facilitate this effort, we develop a non-unitary particle representation of the Poincar\'e group, replacing the classical scalar field with a 5-vector matter field. We further augment the vierbein into a new $5\times5$ f\"unfbein, which `solders' the 5-vector field to $\{x^a\}$. In so doing, we form a new intuition for the Poincar\'e symmetries of scalar field theory. This effort recasts `spacetime data', stored in the derivatives of the scalar field, as `matter field data', stored in the 5-vector field itself. We discuss the physical implications of this `Poincar\'e lift', including the readmittance of an absolute reference frame into relativistic field theory. In a companion paper, we demonstrate that this theoretical development, here construed in a continuous universe, enables the description of a discrete universe that preserves the 10 infinitesimal Poincar\'e symmetries and their conservation laws.