Stellar Dynamics around a Massive Black Hole I: Secular Collisionless Theory

TL;DR

This paper develops a collisionless, secular theory for stellar systems orbiting a massive black hole, incorporating relativistic effects and external influences, and analyzes their stability and equilibrium configurations.

Contribution

It introduces a secular collisionless Boltzmann equation for Keplerian stellar systems, including relativistic corrections and external sources, and proves stability of certain disk configurations.

Findings

Secular dynamics conserve semi-major axes of stars.

Spherical equilibria can support warp-like distortions.

Axisymmetric flat disks are stable if their distribution is monotonic in angular momentum.

Abstract

We present a theory in three parts, of the secular dynamics of a (Keplerian) stellar system of mass $M$ orbiting a black hole of mass $M_\bullet \gg M$. Here we describe the collisionless dynamics; Papers II and III are on the (collisional) theory of Resonant Relaxation. The mass ratio, $\varepsilon = M/M_\bullet \ll 1$, is a natural small parameter implying a separation of time scales between the short Kepler orbital periods and the longer orbital precessional periods. The collisionless Boltzmann equation (CBE) for the stellar distribution function (DF) is averaged over the fast Kepler orbital phase using the method of multiple scales. The orbit-averaged system is described by a secular DF, $F$, in a reduced phase space. $F$ obeys a secular CBE that includes stellar self-gravity, general relativistic corrections up to 1.5 post-Newtonian order, and external sources varying over secular times. Secular dynamics, even with general time dependence, conserves the semi-major axis of every star. This additional integral of motion promotes extra regularity of the stellar orbits, and enables the construction of equilibria, $F_0$, through a secular Jeans theorem. A linearized secular CBE determines the response and stability of $F_0$. Spherical, non-rotating equilibria may support long-lived, warp-like distortions. We also prove that an axisymmetric, zero-thickness, flat disc is secularly stable to all in-plane perturbations, when its DF, $F_0$, is a monotonic function of the angular momentum at fixed energy.