Stability Analysis of Cosmological Perturbations in Bumblebee Model: Parameter Constraints and Gravitational Waves (2509.13958v1)

Abstract: We constrain the parameter space of Bumblebee model within a cosmological background and investigate the properties of gravitational waves under the constrained parameter set. Specifically, we derive the conditions for the absence of ghost, Laplacian, and Tachyon instabilities for perturbations in a cosmological background. By incorporating the observed accelerated expansion of the universe and the observational constraints on tensor gravitational waves, we derive bounds on the parameter space of Bumblebee model. We then examine the polarization modes, propagation speeds, and amplitude relations of gravitational waves within this constrained framework. Our results indicate that the non-minimal coupling parameter $\xi$ must be non-positive, and the lower bound on the Lorentz-violating parameter $\xi b^2$ is constrained to be on the order of $10^{-15}$. Gravitational waves in Bumblebee model are found to propagate in two tensor modes, two vector modes, and one mixed scalar mode. Notably, the tensor gravitational waves travel at subluminal speeds, whereas the vector and scalar gravitational waves propagate at superluminal speeds. These results provide a concrete theoretical framework and specific observational signatures for testing Lorentz invariance in the gravitational sector with future gravitational-wave detectors.