English

Comparison Between Self-Force and Post-Newtonian Dynamics: Beyond Circular Orbits

General Relativity and Quantum Cosmology 2015-06-10 v2

Abstract

The gravitational self-force (GSF) and post-Newtonian (PN) schemes are complementary approximation methods for modelling the dynamics of compact binary systems. Comparison of their results in an overlapping domain of validity provides a crucial test for both methods, and can be used to enhance their accuracy, e.g. via the determination of previously unknown PN parameters. Here, for the first time, we extend such comparisons to noncircular orbits---specifically, to a system of two nonspinning objects in a bound (eccentric) orbit. To enable the comparison we use a certain orbital-averaged quantity U\langle U \rangle that generalizes Detweiler's redshift invariant. The functional relationship U(Ωr,Ωϕ)\langle U \rangle(\Omega_r,\Omega_\phi), where Ωr\Omega_r and Ωϕ\Omega_\phi are the frequencies of the radial and azimuthal motions, is an invariant characteristic of the conservative dynamics. We compute U(Ωr,Ωϕ)\langle U \rangle(\Omega_r,\Omega_\phi) numerically through linear order in the mass ratio qq, using a GSF code which is based on a frequency-domain treatment of the linearized Einstein equations in the Lorenz gauge. We also derive U(Ωr,Ωϕ)\langle U \rangle(\Omega_r,\Omega_\phi) analytically through 3PN order, for an arbitrary qq, using the known near-zone 3PN metric and the generalized quasi-Keplerian representation of the motion. We demonstrate that the O(q)\mathcal{O}(q) piece of the analytical PN prediction is perfectly consistent with the numerical GSF results, and we use the latter to estimate yet unknown pieces of the 4PN expression at O(q)\mathcal{O}(q).

Keywords

Cite

@article{arxiv.1503.01374,
  title  = {Comparison Between Self-Force and Post-Newtonian Dynamics: Beyond Circular Orbits},
  author = {Sarp Akcay and Alexandre Le Tiec and Leor Barack and Norichika Sago and Niels Warburton},
  journal= {arXiv preprint arXiv:1503.01374},
  year   = {2015}
}

Comments

44 pages, 2 figures, 4 tables

R2 v1 2026-06-22T08:44:24.004Z