Momentum flow in black-hole binaries: II. Numerical simulations of equal-mass, head-on mergers with antiparallel spins (0907.0869v1)

Abstract: Research on extracting science from binary-black-hole (BBH) simulations has often adopted a "scattering matrix" perspective: given the binary's initial parameters, what are the final hole's parameters and the emitted gravitational waveform? In contrast, we are using BBH simulations to explore the nonlinear dynamics of curved spacetime. Focusing on the head-on plunge, merger, and ringdown of a BBH with transverse, antiparallel spins, we explore numerically the momentum flow between the holes and the surrounding spacetime. We use the Landau-Lifshitz field-theory-in-flat-spacetime formulation of general relativity to define and compute the density of field energy and field momentum outside horizons and the energy and momentum contained within horizons, and we define the effective velocity of each apparent and event horizon as the ratio of its enclosed momentum to its enclosed mass-energy. We find surprisingly good agreement between the horizons' effective and coordinate velocities. To investigate the gauge dependence of our results, we compare pseudospectral and moving-puncture evolutions of physically similar initial data; although spectral and puncture simulations use different gauge conditions, we find remarkably good agreement for our results in these two cases. We also compare our simulations with the post-Newtonian trajectories and near-field energy-momentum. [Abstract abbreviated; full abstract also mentions additional results.]

• The paper introduces a novel analysis of momentum exchanges in black-hole binaries using the Landau-Lifshitz formalism.
• It employs both pseudospectral and moving-puncture methods to compute effective velocities and capture frame-dragging effects during the plunge phase.
• Findings provide critical insights for gravitational-wave modeling and improving numerical relativity simulations in dynamic spacetime scenarios.

Overview of Momentum Flow in Black-Hole Binaries: Head-On Mergers with Antiparallel Spins

The paper "Momentum flow in black-hole binaries: II. Numerical simulations of equal-mass, head-on mergers with antiparallel spins" presents an advanced computational analysis of the nonlinear dynamics involved in merging black holes using the framework of numerical relativity. Unlike traditional approaches that focus on the ultimate states and emitted gravitational waves from such systems, this paper investigates the intricate momentum exchanges between the black holes and their encompassing curved spacetime during their merger process.

Methodological Approach and Key Results

The authors employ the Landau-Lifshitz formalism within general relativity to dissect momentum density and flow in equal-mass binary black-hole mergers with transverse, antiparallel spins. The effective velocity of the merging horizons is deduced by computing the ratio of enclosed momentum to the total enclosed mass-energy. Using both pseudospectral and moving-puncture methodologies, the paper confirms surprising concordance between calculated effective and coordinate velocities of the horizons throughout the process, which substantiates the robustness of their numerical frameworks.

A significant finding is that during the plunge phase, the black holes experience frame-dragging-induced accelerations leading to substantial speeds orthogonal to their initial motion, peaking at around 1000 km/s. Following the event horizon merger, the common horizon instigates the engulfment of previously external upward field momentum, briefly inducing a reverse acceleration ("kick"). This leads to the emission of gravitational wave bursts, with simulations predicting a residual effective velocity of approximately 20 km/s in the upward direction, aligning with the recoil velocity extracted from the gravitational radiation's linear momentum.

Implications and Theoretical Insights

The results of this research deliver crucial insights into the intricate details of spacerodynamical momentum exchanges in the intense gravitational fields of black-hole binaries. By applying the Landau-Lifshitz formalism, it opens avenues for deeper understanding of momentum dynamics beyond the scattering matrix approach, particularly beneficial for theoretical models studying gravitational wave signals and black-hole astrophysics.

Moreover, the comparative analysis with both spectral and puncture evolutions offers a potential pathway to mitigate gauge dependency in black-hole momentum studies, enhancing the reliability of numerical relativity solutions. This holds significant implications for developing physically accurate and computationally efficient simulations of complex, dynamical spacetime configurations.

Future Directions

The validated methodology encourages further exploration into more astrophysically pertinent scenarios such as inspiraling superkick configurations and BBH systems with varied mass ratios or spins. Extending the formalism to paper angular momentum exchanges during inspiral phases or to configurations with larger spins could yield additional critical data for gravitational-wave astronomy.

In sum, this paper makes a substantive contribution to our comprehension of the fundamental processes governing highly dynamic spacetime scenarios, providing a solid foundation for future computational and theoretical developments in numerical relativity and gravitational wave science.