David Merritt
Published 2015-05-28Version 1
An algorithm is described for evolving the phase-space density of stars or compact objects around a massive black hole at the center of a galaxy. The technique is based on numerical integration of the Fokker-Planck equation in energy-angular momentum space, f(E,L,t), and includes, for the first time, diffusion coefficients that describe the effects of both random and correlated encounters (resonant relaxation), as well as energy loss due to emission of gravitational waves. Destruction or loss of stars into the black hole are treated by means of a detailed boundary-layer analysis. Performance of the algorithm is illustrated by calculating two-dimensional, time-dependent and steady-state distribution functions and their corresponding loss rates.
Comments: 26 pages, 10 figures
Journal: The Astrophysical Journal, Volume 804, Issue 1, article id. 52 (2015)
Rotating Accretion Flows: From Infinity to the Black Hole
Scaling relations between black holes and their host galaxies: comparing theoretical and observational measurements, and the impact of selection effects
On the Offset of Barred Galaxies From the Black Hole $M_{BH}$-$σ$ Relationship
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