A proof of Friedman's ergosphere instability for scalar waves

Abstract

Let (M3+1,g) be a real analytic, stationary and asymptotically flat spacetime with a non-empty ergoregion E and no future event horizon H+. On such spacetimes, Friedman provided a heuristic argument that the energy of certain solutions φ of gφ=0 grows to +∞ as time increases. In this paper, we provide a rigorous proof of Friedman's instability. Our setting is, in fact, more general. We consider smooth spacetimes (Md+1,g), for any d2, not necessarily globally real analytic. We impose only a unique continuation condition for the wave equation across the boundary ∂E of E on a small neighborhood of a point p∈∂E. This condition always holds if (M,g) is analytic in that neighborhood of p, but it can also be inferred in the case when (M,g) possesses a second Killing field such that the span of and the stationary Killing field T is timelike on ∂E. We also allow the spacetimes (M,g) under consideration to possess a (possibly empty) future event horizon H+, such that, however, H+E= (excluding, thus, the Kerr exterior family). As an application of our theorem, we infer an instability result for the acoustical wave equation on the hydrodynamic vortex, a phenomenon first investigated numerically by Oliveira, Cardoso and Crispino. Furthermore, as a side benefit of our proof, we provide a derivation, based entirely on the vector field method, of a Carleman-type estimate on the exterior of the ergoregion for a general class of stationary and asymptotically flat spacetimes.