Superradiant scattering by rotating black-bounce black holes

Abstract

We investigate superradiant scattering off a rotating regular black hole described by a black-bounce metric which generalizes the Kerr spacetime of mass M and specific angular momentum a through a regularization parameter p and two deformation exponents (k,n). Focusing on massless (,m)=(1,1) scalar modes, we explore the parameter space and compute amplification factors by numerically integrating the separated radial Klein-Gordon equation. We track the peak amplification and the corresponding frequency across the (a/M,p/M) parameter space for several combinations of k and n. We find that increasing n systematically enhances superradiance, whereas increasing k tends to suppress it. In particular, certain configurations yield amplification levels up to 98% larger than the maximum amplification for standard Kerr black holes.