Gravitational self-torque and spin precession in compact binaries
arXiv:1312.0775 · doi:10.1103/PhysRevD.89.064011
Abstract
We calculate the effect of self-interaction on the "geodetic" spin precession of a compact body in a strong-field orbit around a black hole. Specifically, we consider the spin precession angle $Ï$ per radian of orbital revolution for a particle carrying mass $μ$ and spin $s \ll (G/c) μ^2$ in a circular orbit around a Schwarzschild black hole of mass $M \gg μ$. We compute $Ï$ through $O(μ/M)$ in perturbation theory, i.e, including the correction $δÏ$ (obtained numerically) due to the torque exerted by the conservative piece of the gravitational self-field. Comparison with a post-Newtonian (PN) expression for $δÏ$, derived here through 3PN order, shows good agreement but also reveals strong-field features which are not captured by the latter approximation. Our results can inform semi-analytical models of the strong-field dynamics in astrophysical binaries, important for ongoing and future gravitational-wave searches.
5 pages, 1 table, 1 figure. Minor changes to match published version