Antikick Relation in High-Energy Head-On Collisions of Spinning Black Holes
Abstract
The collision of black holes at relativistic speeds probes gravity in its most extreme dynamical regime. While the maximum gravitational recoil from grazing high-energy collisions (≈28\,562~km/s, i.e., 0.1c) and the maximum radiated energy E rad and remnant spin αf from such encounters (E rad/M ADM≈32\% where M ADM is the ADM mass, and αf≈0.987) have been established previously~Healy:2022jbh,Healy:2024lhl, here we focus on the head-on high-energy collision of equal-mass spinning black holes and on the detailed structure of the resulting recoil. Performing a sequence of full numerical simulations for spin magnitudes s=0.5,0.65, and 0.8 over a range of initial momenta γv, we characterize the peak recoil Vp, the final recoil Vf, and the antikick ΔV Vf-Vp, and we provide phenomenological fits of their dependence on γv and s. We complement these results with a zero-frequency-limit (ZFL) analysis of the radiated energy and momentum, a quasinormal-mode model of the antikick, and a superposed boosted double-Kerr close-limit estimate. We find that in the relativistic regime (γv>1) the peak and final recoil are directly proportional, Vp≈7.4\,Vf (equivalently ΔV ≈-6.4\,Vf), largely independent of both the initial momentum and the spin magnitude, pointing to a common post-merger relaxation. While the ZFL predicts a leading linear-in-spin dependence, the close-limit analysis predicts a leading s3 dependence of the recoil amplitude; with the three spin magnitudes studied here the empirical exponent is s1.270.08, motivating an even higher energy collision spin sequence study.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.