Cosmological perturbations and gravitational waves in the general Einstein-vector theory

TL;DR

The paper analyzes the stability and gravitational-wave phenomenology of the four-dimensional general Einstein-vector theory on a cosmological background. By exploiting an SVT decomposition, it shows that scalar, vector, and tensor perturbations decouple and studies their linear stability, finding up to six dynamical DOF (two tensor, two vector, two scalar) depending on the parameter region. In the small-scale limit, tensor GWs yield two propagating modes with a speed $c_t$ that must match the light speed to satisfy GW170817 constraints, which constrains the couplings to three viable cases; vector GWs are generally superluminal when present, and scalar GW content depends sensitively on $ar{A}$ and the couplings, with ghost and Laplacian instabilities restricting the parameter space. Overall, the theory offers rich cosmological and GW phenomenology, including potential signatures for dark energy and modified gravity tests with upcoming GW detectors and cosmological surveys.

Abstract

We investigate the stability and gravitational waves (GWs) in the four-dimensional general Einstein-vector theory in a cosmological background. The theory accommodates up to six propagating degrees of freedom, comprising two tensor, two vector, and two scalar modes, in addition to matter perturbations. In certain regions of the parameter space, the number of scalar degrees of freedom is reduced to one or even zero. To investigate the stability, we systematically analyze ghost, Laplacian, and tachyonic instabilities at the linear perturbative level. The stability conditions are easily satisfied for tensor perturbations, but impose nontrivial constraints on the parameter space for vector perturbations. Furthermore, in the presence of a nonvanishing background vector field, the scalar sector becomes unstable at small wavenumbers $|\vec{k}|$. In the small-scale limit ($|\vec{k}|\rightarrow\infty$), we further investigate the GW properties of the general Einstein-vector theory within the stable parameter space, including the number of independent modes, their propagation speeds, and observational constraints from GW experiments. We find that there are at most two tensor modes, two vector modes, and one scalar mode. Notably, vector GWs propagate superluminally, yet they are forbidden if tensor GWs travel exactly at light speed. This distinctive feature provides a key observational signature for testing the theory.