Mode stability and shallow quasinormal modes of Kerr-de Sitter black holes away from extremality
Abstract
A Kerr-de Sitter black hole is a solution (M,g,m,a) of the Einstein vacuum equations with cosmological constant >0. It describes a black hole with mass m>0 and specific angular momentum a∈R. We show that for any ε>0 there exists δ>0 so that mode stability holds for the linear scalar wave equation g,m,aφ=0 when |a/m|∈[0,1-ε] and m2<δ. In fact, we show that all quasinormal modes σ in any fixed half space σ>-C are equal to 0 or -i/3(n+o(1)), n∈N, as m2 0. We give an analogous description of quasinormal modes for the Klein-Gordon equation. We regard a Kerr-de Sitter black hole with small m2 as a singular perturbation either of a Kerr black hole with the same angular momentum-to-mass ratio, or of de Sitter spacetime without any black hole present. We use the mode stability of subextremal Kerr black holes, proved by Whiting and Shlapentokh-Rothman, as a black box; the quasinormal modes described by our main result are perturbations of those of de Sitter space. Our proof is based on careful uniform a priori estimates, in a variety of asymptotic regimes, for the spectral family and its de Sitter and Kerr model problems in the singular limit m2 0.
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