The Lazarus project: A pragmatic approach to binary black hole evolutions

TL;DR

This paper introduces a combined numerical and perturbative approach to simulate binary black hole mergers, enabling the computation of complete gravitational waveforms from inspiral to ringdown.

Contribution

It develops a pragmatic method integrating 3D numerical simulations with close-limit perturbation theory for accurate black hole binary evolution modeling.

Findings

Successfully computed complete waveforms for binary black hole systems.

Validated the approach by evolving a Kerr black hole and analyzing spurious radiation.

Outlined extensions for improved simulations and astrophysical applications.

Abstract

We present a detailed description of techniques developed to combine 3D numerical simulations and, subsequently, a single black hole close-limit approximation. This method has made it possible to compute the first complete waveforms covering the post-orbital dynamics of a binary black hole system with the numerical simulation covering the essential non-linear interaction before the close limit becomes applicable for the late time dynamics. To determine when close-limit perturbation theory is applicable we apply a combination of invariant a priori estimates and a posteriori consistency checks of the robustness of our results against exchange of linear and non-linear treatments near the interface. Once the numerically modeled binary system reaches a regime that can be treated as perturbations of the Kerr spacetime, we must approximately relate the numerical coordinates to the perturbative background coordinates. We also perform a rotation of a numerically defined tetrad to asymptotically reproduce the tetrad required in the perturbative treatment. We can then produce numerical Cauchy data for the close-limit evolution in the form of the Weyl scalar $\psi_4$ and its time derivative $\partial_t\psi_4$ with both objects being first order coordinate and tetrad invariant. The Teukolsky equation in Boyer-Lindquist coordinates is adopted to further continue the evolution. To illustrate the application of these techniques we evolve a single Kerr hole and compute the spurious radiation as a measure of the error of the whole procedure. We also briefly discuss the extension of the project to make use of improved full numerical evolutions and outline the approach to a full understanding of astrophysical black hole binary systems which we can now pursue.