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Merger states and final states of black hole coalescences: a numerical-relativity-assisted effective-one-body approach

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arxiv 1307.2868 v2 pith:HDPMHB2F submitted 2013-07-10 gr-qc

Merger states and final states of black hole coalescences: a numerical-relativity-assisted effective-one-body approach

classification gr-qc
keywords blackeffective-one-bodyfinalmergerangularbinarycoalescingenergy
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We study to what extent the effective-one-body description of the dynamical state of a nonspinning, coalescing binary black hole (considered either at merger, or after ringdown) agrees with numerical relativity results. This comparison uses estimates of the integrated losses of energy and angular momentum during ringdown, inferred from recent numerical-relativity data. We find that the values, predicted by the effective-one-body formalism, of the energy and angular momentum of the system agree at the per mil level with their numerical-relativity counterparts, both at merger and in the final state. This gives a new confirmation of the ability of effective-one-body theory to accurately describe the dynamics of binary black holes even in the strong-gravitational-field regime. Our work also provides predictions (and analytical fits) for the final mass and the final spin of coalescing black holes for all mass ratios

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Cited by 2 Pith papers

Reviewed papers in the Pith corpus that reference this work. Sorted by Pith novelty score.

  1. Cusp Formation in Merging Black Hole Horizons

    gr-qc 2026-05 unverdicted novelty 6.0

    Numerical study of cusp formation on horizons in head-on non-spinning black hole mergers, with analysis of mass and multipole behavior at the cusp and a proposed phenomenological model.

  2. Cusp Formation in Merging Black Hole Horizons

    gr-qc 2026-05 unverdicted novelty 5.0

    Numerical simulations of head-on black hole mergers reveal cusp formation on horizons, with mass and multipole moments behaving in ways that link initial and final black hole states via a phenomenological model.