Highly Damped Quasinormal Modes of Kerr Black Holes: A Complete Numerical Investigation
Abstract
We compute for the first time very highly damped quasinormal modes of the (rotating) Kerr black hole. Our numerical technique is based on a decoupling of the radial and angular equations, performed using a large-frequency expansion for the angular separation constantsAl m. This allows us to go much further in overtone number than ever before. We find that the real part of the quasinormal frequencies approaches a non-zero constant value which does not depend on the spin s of the perturbing field and on the angular index l: ωR=m(a). We numerically compute (a). Leading-order corrections to the asymptotic frequency are likely to be of order 1/ωI. The imaginary part grows without bound, the spacing between consecutive modes being a monotonic function of a.
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