Dynamic Aspects of Bumblebee Gravity: Post-Newtonian Approach

Abstract

In this work, we investigate the dynamic aspects of Bumblebee gravity via the parameterized post-Newtonian method. We find that the PPN framework is self-consistent up to 1.5PN order if and only if λ= -ξ/2, which corresponds to a direct coupling between the Bumblebee field Bμ and the Einstein tensor. The requirement of tachyonic stability restricts the Bumblebee potential to satisfy V''(0)=0. In the specific case where λ= -ξ/2, the resulting PPN metric yields non-vanishing values for the parameters α1 and α2, as well as a novel PPN potential UB that exhibits a logarithmic asymptotic growth. The vanishing of the potential UB necessitates the additional constraints ξ= κ/2 or V(3)(0) = 0. These results signify the presence of preferred-frame effects, a direct consequence of the Lorentz symmetry breaking in the model. In the limit of small , we obtain α2 -2, which yields a constraint of || 1.6× 10-9 based on pulsar timing observations.