Gravitational partial-wave absorption from scattering amplitudes
Abstract
We study gravitational absorption effects using effective on-shell scattering amplitudes. We develop an in-in probability-based framework involving plane- and partial-wave coherent states for the incoming wave to describe the interaction of the wave with a black hole or another compact object. We connect this framework to a simplified single-quantum analysis. The basic ingredients are mass-changing three-point amplitudes, which model the leading absorption effects and a spectral-density function of the black hole. As an application, we consider a non-spinning black hole that may start spinning as a consequence of the dynamics. The corresponding amplitudes are found to correspond to covariant spin-weighted spherical harmonics, the properties of which we formulate and make use of. We perform a matching calculation to general-relativity results at the cross-section level and derive the effective absorptive three-point couplings. They are found to behave as , where is the spin of the outgoing massive state.
Cite
@article{arxiv.2307.07504,
title = {Gravitational partial-wave absorption from scattering amplitudes},
author = {Rafael Aoude and Alexander Ochirov},
journal= {arXiv preprint arXiv:2307.07504},
year = {2023}
}
Comments
33 pages + appendices + refs, 5 figures; v3 sections rearranged, formulae unchanged, published version