Spin-orbit precession for eccentric black hole binaries at first order in the mass ratio
arXiv:1608.04811 · doi:10.1088/1361-6382/aa61d6
Abstract
We consider spin-orbit ("geodetic") precession for a compact binary in strong-field gravity. Specifically, we compute $Ï$, the ratio of the accumulated spin-precession and orbital angles over one radial period, for a spinning compact body of mass $m_1$ and spin $s_1$, with $s_1 \ll G m_1^2/c$, orbiting a non-rotating black hole. We show that $Ï$ can be computed for eccentric orbits in both the gravitational self-force and post-Newtonian frameworks, and that the results appear to be consistent. We present a post-Newtonian expansion for $Ï$ at next-to-next-to-leading order, and a Lorenz-gauge gravitational self-force calculation for $Ï$ at first order in the mass ratio. The latter provides new numerical data in the strong-field regime to inform the Effective One-Body model of the gravitational two-body problem. We conclude that $Ï$ complements the Detweiler redshift $z$ as a key invariant quantity characterizing eccentric orbits in the gravitational two-body problem.
Matches the published version in CQG