Post-Newtonian expansion of the spin-precession invariant for eccentric-orbit non-spinning extreme-mass-ratio inspirals to 9PN and e16

Abstract

We calculate the eccentricity dependence of the high-order post-Newtonian (PN) expansion of the spin-precession invariant for eccentric-orbit extreme-mass-ratio inspirals with a Schwarzschild primary. The series is calculated in first-order black hole perturbation theory through direct analytic expansion of solutions in the Regge-Wheeler-Zerilli formalism, using a code written in Mathematica. Modes with small values of l are found via the Mano-Suzuki-Takasugi (MST) analytic function expansion formalism for solutions to the Regge-Wheeler equation. Large-l solutions are found by applying a PN expansion ansatz to the Regge-Wheeler equation. Previous work has given to 9.5PN order and to order e2 (i.e., the near circular orbit limit). We calculate the expansion to 9PN but to e16 in eccentricity. It proves possible to find a few terms that have closed-form expressions, all of which are associated with logarithmic terms in the PN expansion. We also compare the numerical evaluation of our PN expansion to prior numerical calculations of in close orbits to assess its radius of convergence. We find that the series is not as rapidly convergent as the one for the redshift invariant at r 10M but still yielding 1\% accuracy for eccentricities e 0.25.