Analytical expression for a class of spherically symmetric solutions in Lorentz breaking massive gravity

Abstract

We present a detailed study of the spherically symmetric solutions in Lorentz breaking massive gravity. There is an undetermined function F(X, w1, w2, w3) in the action of St\"uckelberg fields Sφ=4∫d4x-gF, which should be resolved through physical means. In the general relativity, the spherically symmetric solution to the Einstein equation is a benchmark and its massive deformation also play a crucial role in Lorentz breaking massive gravity. F will satisfy the constraint equation T01=0 from the spherically symmetric Einstein tensor G01=0, if we maintain that any reasonable physical theory should possess the spherically symmetric solutions. The St\"uckelberg field φi is taken as a 'hedgehog' configuration φi=φ(r)xi/r, whose stability is guaranteed by the topological one. Under this ans\"atz, T01=0 is reduced to dF=0. The functions F for dF=0 form a commutative ring RF. We obtain a general expression of solution to the functional differential equation with spherically symmetry if F∈ RF. If F∈ RF and ∂F/∂ X=0, the functions F form a subring SF⊂ RF. We show that the metric is Schwarzschild, AdS or dS if F∈ SF. When F∈ RF but F SF, we will obtain some new metric solutions. Using the general formula and the basic property of function ring RF, we give some analytical examples and their phenomenological applications. Furthermore, we also discuss the stability of gravitational field by the analysis of Komar integral and the results of QNMs.