High-energy interactions of charged black holes in full general relativity I: Zoom-whirl orbits and universality with the irreducible mass
Abstract
We simulate high-energy scattering of equal-mass, nonspinning black holes endowed with like charges in full general relativity while varying the impact parameter b. We show that electrodynamics does not suppress zoom-whirl orbits for at least charge-to-mass ratios λ = 0.1, 0.4, 0.6. However, we find that as λ increases, the immediate merger and scattering thresholds defining the zoom-whirl regime move to smaller impact parameter b/M ADM, with M ADM designating the binary black hole gravitational mass. This demonstrates that charge leaves observable imprints in key properties at energy scales where charge has negligible influence in head-on collisions. Additionally, we find that these threshold impact parameters become universal, i.e., charge-independent, when we normalize b by the sum of the initial BH irreducible masses in the binary (b/M irr). This is the first explicit demonstration that the irreducible mass, which is proportional to the black hole areal radius, defines a fundamental gauge-invariant length scale governing horizon scale scattering events in the strong-field, dynamical spacetime regime.
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