Osculating orbits in Schwarzschild spacetime, with an application to extreme mass-ratio inspirals

TL;DR

This paper introduces a method to model bound orbits in Schwarzschild spacetime using osculating geodesics, with applications to extreme mass-ratio inspirals, highlighting the significance of conservative forces on orbital evolution.

Contribution

The paper develops evolution equations for orbital elements assuming in-plane forces, applicable to strong orbits without small-force restrictions, and applies this to analyze two-body systems in Schwarzschild spacetime.

Findings

Conservative forces significantly affect long-term orbital phase.

The method reveals limitations of the radiative approximation in gravitational self-force.

Application to hybrid Schwarzschild/post-Newtonian equations demonstrates the importance of conservative terms.

Abstract

We present a method to integrate the equations of motion that govern bound, accelerated orbits in Schwarzschild spacetime. At each instant the true worldline is assumed to lie tangent to a reference geodesic, called an osculating orbit, such that the worldline evolves smoothly from one such geodesic to the next. Because a geodesic is uniquely identified by a set of constant orbital elements, the transition between osculating orbits corresponds to an evolution of the elements. In this paper we derive the evolution equations for a convenient set of orbital elements, assuming that the force acts only within the orbital plane; this is the only restriction that we impose on the formalism, and we do not assume that the force must be small. As an application of our method, we analyze the relative motion of two massive bodies, assuming that one body is much smaller than the other. Using the hybrid Schwarzschild/post-Newtonian equations of motion formulated by Kidder, Will, and Wiseman, we treat the unperturbed motion as geodesic in a Schwarzschild spacetime whose mass parameter is equal to the system's total mass. The force then consists of terms that depend on the system's reduced mass. We highlight the importance of conservative terms in this force, which cause significant long-term changes in the time-dependence and phase of the relative orbit. From our results we infer some general limitations of the radiative approximation to the gravitational self-force, which uses only the dissipative terms in the force.