Energy versus Angular Momentum in Black Hole Binaries

Abstract

Using accurate numerical relativity simulations of (nonspinning) black-hole binaries with mass ratios 1:1, 2:1 and 3:1 we compute the gauge invariant relation between the (reduced) binding energy E and the (reduced) angular momentum j of the system. We show that the relation E(j) is an accurate diagnostic of the dynamics of a black-hole binary in a highly relativistic regime. By comparing the numerical-relativity E NR (j) curve with the predictions of several analytic approximation schemes, we find that, while the usual, non-resummed post-Newtonian-expanded E PN (j) relation exhibits large and growing deviations from E NR (j), the prediction of the effective one-body formalism, based purely on known analytical results (without any calibration to numerical relativity), agrees strikingly well with the numerical-relativity results.