The bumblebee field excitations in a cosmological braneworld

Abstract

We investigated the effects of the spacetime curvature and extra dimensions on the excitations of a self-interacting vector field known as the bumblebee field. The self-interacting quadratic potential breaks the gauge invariance and the vacuum expectation value (VEV) of the bumblebee field bM violates the local particle Lorentz symmetry. By assuming the bumblebee field living in a AdS5 bulk, we found an exponential suppression of the self-interacting constant λ and the bumblebee VEV along the extra dimension. The fluctuations of the bumblebee upon the VEV can be decomposed into transverse and longitudinal modes with respect to bM. Despite the curvature, the transverse mode acquires massive Kaluza-Klein towers, while the longitudinal mode acquires LV mass λ b2. On the other hand, the current conservation law prevents massive Kaluza-Klein modes for the longitudinal mode. For a spacelike bM along the extra dimension and assuming a FRW 3-brane embedded in the AdS5 yields to an additional dissipative term to the longitudinal mode. The cosmological expansion leads to decay of the longitudinal mode in a time t ≈ H-1, where H=a/a is the Hubble parameter and a(t) is the scale factor. For a timelike bM, the longitudinal mode does not propagate on the brane and its amplitude decays in time with a-3 and in the extra dimension with z-λ b2l2.