Polarization modes of gravitational waves in general symmetric teleparallel gravity

TL;DR

This paper explores the polarization modes of gravitational waves in symmetric teleparallel gravity, revealing tensor, vector, and scalar modes, and analyzing their propagation speeds and conditions, especially considering hypermomentum effects.

Contribution

It provides a comprehensive analysis of gravitational wave polarization modes in the most general symmetric teleparallel gravity, including the effects of hypermomentum and special theories like $f(Q)$ gravity.

Findings

Tensor modes propagate at the speed of light.

Vector modes exist under specific parameter conditions.

Longitudinal modes always propagate at the speed of light with hypermomentum.

Abstract

In this paper, we investigate the polarization modes of gravitational waves within the most general symmetric teleparallel gravity theory that allows for second-order field equations We consider both scenarios where test particles either carry or do not carry a hypermomentum charge. Our findings reveal the existence of tensor, vector, and scalar modes of gravitational waves. Firstly, the theory supports the + and $\times$ tensor modes propagating at the speed of light. Secondly, in the case where particles do not carry hypermomentum, vector modes propagating at the speed of light exist only within a very specific parameter space. However, when particles do carry hypermomentum, there are two shear modes that propagate at the speed of light, while the vector-$x$ and vector-$y$ modes emerge only under very specific conditions. Thirdly, in the presence of hypermomentum, there is always a longitudinal mode propagating at the speed of light. The universal existence of the shear modes and the longitudinal mode in the presence of hypermomentum is a key feature of symmetric teleparallel gravity, distinguishing it from the Riemannian framework through gravitational wave polarization detection. We also analyze the polarization modes in two widely studied special theories: $f(Q)$ theory and quadratic non-metricity theory. Our study reveals that, within the $f(Q)$ gravity framework, it is crucial to assume that matter fields are independent of the connection, as any dependence would lead to unphysical results.