Generalized Abelian Gauge Field Theory under Rotor Model

TL;DR

This paper extends abelian gauge field theory to include higher-order derivatives via the rotor model in arbitrary dimensions, revealing how multiple rotor contributions modify the gauge fields and their dynamics.

Contribution

It introduces a generalized framework for abelian gauge theories incorporating successive rotor models, expanding the understanding of higher derivative effects in gauge fields.

Findings

$n$ rotor contributes to $oxed{ abla^n} T^{\mu}$ fields

Transformation of gauge fields to higher derivatives $oxed{ abla^{n}} T^{\mu}$ and $oxed{ abla^{n}} G_{\mu u}$

Restoration of standard theory at $n=0$ case

Abstract

Gauge field theory with rank-one field $T_{\mu}$ is a quantum field theory that describes the interaction of elementary spin-1 particles, of which being massless to preserve gauge symmetry. In this paper, we give a generalized, extended study of abelian gauge field theory under successive rotor model in general $D$-dimensional flat spacetime for spin-1 particles in the context of higher order derivatives. We establish a theorem that $n$ rotor contributes to the $\Box^n T^{\mu}$ fields in the integration-by-parts formalism of the action. This corresponds to the transformation of gauge field $T^{\mu} \rightarrow \Box^n T^{\mu}$ and gauge field strength $G_{\mu\nu}\rightarrow \Box^n G_{\mu\nu} $ in the action. The $n=0$ case restores back to the standard abelian gauge field theory. The equation of motion and Noether's conserved current of the theory are also studied.