From Poincare Invariance to Gauge Theories: Yang-Mills and General Relativity

TL;DR

This paper derives Yang-Mills and general relativity theories from Poincare invariance and covariant derivatives, emphasizing gauge symmetries emerging from Lorentz invariance rather than matter action symmetries.

Contribution

It presents a novel derivation of gauge theories and gravity directly from Poincare invariance and covariant derivatives, offering a new perspective on their foundational principles.

Findings

Lorentz invariance induces gauge symmetry for massless tensors.

Framework recovers Yang-Mills and general relativity in connection formulations.

Derivation of interacting Dirac equation in gauge and gravitational fields.

Abstract

This article is founded on two fundamental principles: the principle field equations introduced in Refs. \cite{S, S1, S2} and the Fock-Ivanenko covariant derivatives \cite{FI, F}. The former yields the equations of motion for free fields of arbitrary spin and helicity. In the massless case, it also dictates that Lorentz transformations for tensor fields acquire an additional term, which takes the form of a gauge transformation \cite{W, S1}. The latter principle, the Fock-Ivanenko derivative, introduces interactions based on the intrinsic and Poincare groups. This framework allows us to recover a complete Yang-Mills theory, as well as general relativity in the connection-based formulations of Palatini and Ashtekar, both of which are theories with local gauge symmetries. While the standard approach begins with the symmetries of a matter action, we will instead derive dynamics directly from Poincare invariance. This perspective reveals that for free fields, Lorentz invariance induces the gauge symmetry of massless tensors. A proper definition of these gauge transformations, in turn, requires the covariant derivatives provided by the Fock-Ivanenko approach. Considering matter fields, we derive the interacting Dirac equation in the presence of Yang-Mills and gravitational fields from its free counterpart.