Gravitational self-force and the effective-one-body formalism between the innermost stable circular orbit and the light ring

Abstract

We compute the conservative piece of the gravitational self-force (GSF) acting on a particle of mass m1 as it moves along an (unstable) circular geodesic orbit between the innermost stable circular orbit (ISCO) and the light ring of a Schwarzschild black hole of mass m2>> m1. More precisely, we construct the function huu(x) = hμ uμ u (related to Detweiler's gauge-invariant "redshift" variable), where hμ is the regularized metric perturbation in the Lorenz gauge, uμ is the four-velocity of m1, and x= [Gc-3(m1+m2)]2/3 is an invariant coordinate constructed from the orbital frequency . In particular, we explore the behavior of huu just outside the "light ring" at x=1/3, where the circular orbit becomes null. Using the recently discovered link between huu and the piece a(u), linear in the symmetric mass ratio , of the main radial potential A(u,) of the Effective One Body (EOB) formalism, we compute a(u) over the entire domain 0<u<1/3. We find that a(u) diverges at the light-ring as ~0.25 (1-3u)-1/2, explain the physical origin of this divergence, and discuss its consequences for the EOB formalism. We construct accurate global analytic fits for a(u), valid on the entire domain 0<u<1/3 (and possibly beyond), and give accurate numerical estimates of the values of a(u) and its first 3 derivatives at the ISCO, as well as the O() shift in the ISCO frequency. In previous work we used GSF data on slightly eccentric orbits to compute a certain linear combination of a(u) and its first two derivatives, involving also the O() piece d(u) of a second EOB radial potential D(u,). Combining these results with our present global analytic representation of a(u), we numerically compute d(u)$ on the interval 0<u≤ 1/6.