# The statistical mechanics of relativistic orbits around a massive black   hole

**Authors:** Ben Bar-Or, Tal Alexander

arXiv: 1404.0351 · 2014-12-04

## TL;DR

This paper develops a statistical mechanics framework to analyze how correlated Gaussian noise influences relativistic stellar orbits around massive black holes, revealing a barrier effect in angular momentum evolution due to Schwarzschild precession.

## Contribution

It introduces a phase-averaged stochastic Hamiltonian approach and derives the Fokker-Planck equation for correlated Gaussian noise, highlighting the impact of noise smoothness on orbital dynamics.

## Key findings

- Angular momentum evolution is suppressed below a critical value j_b.
- A Schwarzschild precession-induced barrier in angular momentum is identified.
- The barrier's significance depends on the noise's temporal smoothness and frequency.

## Abstract

Stars around a massive black hole (MBH) move on nearly fixed Keplerian orbits, in a centrally-dominated potential. The random fluctuations of the discrete stellar background cause small potential perturbations, which accelerate the evolution of orbital angular momentum by resonant relaxation. This drives many phenomena near MBHs, such as extreme mass-ratio gravitational wave inspirals, the warping of accretion disks, and the formation of exotic stellar populations. We present here a formal statistical mechanics framework to analyze such systems, where the background potential is described as a correlated Gaussian noise. We derive the leading order, phase-averaged 3D stochastic Hamiltonian equations of motion, for evolving the orbital elements of a test star, and obtain the effective Fokker-Planck equation for a general correlated Gaussian noise, for evolving the stellar distribution function. We show that the evolution of angular momentum depends critically on the temporal smoothness of the background potential fluctuations. Smooth noise has a maximal variability frequency $\nu_{\max}$. We show that in the presence of such noise, the evolution of the normalized angular momentum $j=\sqrt{1-e^{2}}$ of a relativistic test star, undergoing Schwarzschild (in-plane) General Relativistic precession with frequency $\nu_{GR}/j^{2}$, is exponentially suppressed for $j<j_{b}$, where $\nu_{GR}/j_{b}^{2}\sim\nu_{\max}$, due to the adiabatic invariance of the precession against the slowly varying random background torques. This results in an effective Schwarzschild precession-induced barrier in angular momentum. When $j_{b}$ is large enough, this barrier can have significant dynamical implications for processes near the MBH.

## Full text

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## Figures

10 figures with captions in the complete paper: https://tomesphere.com/paper/1404.0351/full.md

## References

30 references — full list in the complete paper: https://tomesphere.com/paper/1404.0351/full.md

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Source: https://tomesphere.com/paper/1404.0351