The effective-one-body theory (EOB) describes the conservative dynamics of compact binary systems in terms of an effective Hamiltonian approach. The Hamiltonian for moderately eccentric motion of two non-spinning compact objects in the extreme mass-ratio limit is given in terms of three potentials: a(v),dˉ(v),q(v). By generalizing the first law of mechanics for (non-spinning) black hole binaries to eccentric orbits, [\prd{\bf92}, 084021 (2015)] recently obtained new expressions for dˉ(v) and q(v) in terms of quantities that can be readily computed using the gravitational self-force approach. Using these expressions we present a new computation of the EOB potential q(v) by combining results from two independent numerical self-force codes. We determine q(v) for inverse binary separations in the range 1/1200≤v≲1/6. Our computation thus provides the first-ever strong-field results for q(v). We also obtain dˉ(v) in our entire domain to a fractional accuracy of ≳10−8. We find to our results are compatible with the known post-Newtonian expansions for dˉ(v) and q(v) in the weak field, and agree with previous (less accurate) numerical results for dˉ(v) in the strong field.
@article{arxiv.1512.03392,
title = {Numerical computation of the EOB potential q using self-force results},
author = {Sarp Akcay and Maarten van de Meent},
journal= {arXiv preprint arXiv:1512.03392},
year = {2016}
}
Comments
4 figures, numerical data at the end. Fixed the typos, added the journal reference