Asymptotics of Linear Waves and Resonances with Applications to Black Holes

Author(s)

Dyatlov, Semen

Abstract

We describe asymptotic behavior of linear waves on Kerr(–de Sitter) black holes and more general Lorentzian manifolds, providing a quantitative analysis of the ringdown phenomenon. In particular we prove that if the initial data is localized at frequencies ∼λ≫1, then the energy norm of the solution is bounded by O(λ[superscript 1/2]e[superscript -(νmin−ε)t/2]) + O(λ[superscript−∞]), for t ≤ C log λ,where ν[subscript min] is a natural dynamical quantity. The key tool is a microlocal projector splitting the solution into a component with controlled rate of exponential decay and an O(λe[superscript −(νmin−ε)t]) + O(λ[superscript−∞]) remainder. This splitting generalizes expansions into quasi-normal modes available in completely integrable settings. In the case of generalized Kerr(–de Sitter) black holes satisfying certain natural conditions, quasi-normal modes are localized in bands and satisfy a precise counting law.

Date issued

2015-01

URI

http://hdl.handle.net/1721.1/106830

Department

Massachusetts Institute of Technology. Department of Mathematics

Journal

Communications in Mathematical Physics

Publisher

Springer Berlin Heidelberg

Citation

Dyatlov, Semyon. “Asymptotics of Linear Waves and Resonances with Applications to Black Holes.” Communications in Mathematical Physics 335.3 (2015): 1445–1485.

Version: Author's final manuscript

ISSN

0010-3616

1432-0916