On strong mass segregation around a massive black hole: Implications for lower-frequency gravitational-wave astrophysics

Abstract

We present, for the first time, a clear N-body realization of the strong mass segregation solution for the stellar distribution around a massive black hole. We compare our N-body results with those obtained by solving the orbit-averaged Fokker-Planck (FP) equation in energy space. The N-body segregation is slightly stronger than in the FP solution, but both confirm the robustness of the regime of strong segregation when the number fraction of heavy stars is a (realistically) small fraction of the total population. In view of recent observations revealing a dearth of giant stars in the sub-parsec region of the Milky Way, we show that the time scales associated with cusp re-growth are not longer than (0.1-0.25) × Trlx(rh). These time scales are shorter than a Hubble time for black holes masses 4 × 106 M and we conclude that quasi-steady, mass segregated, stellar cusps may be common around MBHs in this mass range. Since EMRI rates scale as -α, with α ∈ [1\4,1], a good fraction of these events should originate from strongly segregated stellar cusps.