The motion of test bodies with microstructure in gauge gravity models

TL;DR

This paper derives generalized equations of motion for particles with microstructure in a broad class of gauge gravity theories, highlighting the importance of matter microstructure for detecting non-Riemannian geometries.

Contribution

It provides a unified, explicit formalism for particle motion in various gravitational theories, extending known results to non-Riemannian frameworks.

Findings

Unified equations of motion for pole-dipole particles in gauge gravity models.

Identification of matter-gravity couplings specific to non-Riemannian geometries.

Emphasizes the role of matter microstructure in detecting non-Riemannian spacetime features.

Abstract

We report on the explicit form of the equations of motion of pole-dipole particles for a very large class of gravitational theories. The non-Riemannian framework in which the equations are derived allows for a unified description of nearly all known gravitational theories. The propagation equations are obtained with the help of a multipole expansion method from the conservation laws that follow from Noether's theorem. The well-known propagation equations of general relativity, e.g., as given by Mathisson and Papapetrou, represent a special case in our general framework. Our formalism allows for a direct identification of the couplings between the matter currents and the gravitational field strengths in gauge gravity models. In particular, it illustrates the need for matter with microstructure for the detection of non-Riemannian spacetime geometries.