Radiated Angular Momentum and Dissipative Effects in Classical Scattering
Abstract
We present a new formula for the angular momentum carried away by gravitational radiation in classical scattering. This formula, combined with the known expression for the radiated linear momentum , completes the set of radiated Poincare charges due to scattering. We parametrize and by non-perturbative form factors and derive exact relations using the Poincare algebra. There is a contribution to due to static (zero-frequency) modes, which can be derived from Weinberg's soft theorem. Using tools from scattering amplitudes and effective field theory, we calculate the radiated due to the scattering of two spinless particles to third order in Newton's constant , but to all orders in velocity. Our form-factor analysis elucidates a novel relation found by Bini, Damour, and Geralico between energy and angular momentum loss at . Our new results have several nontrivial implications for binary scattering at . We give a procedure to bootstrap an effective radiation reaction force from the loss of Poincare charges due to scattering.
Cite
@article{arxiv.2203.04283,
title = {Radiated Angular Momentum and Dissipative Effects in Classical Scattering},
author = {Aneesh V. Manohar and Alexander K. Ridgway and Chia-Hsien Shen},
journal= {arXiv preprint arXiv:2203.04283},
year = {2022}
}
Comments
5 pages +refs, two figures and one Mathematica ancillary file for table I; minor revision and fixed a typo in the definition of \Delta b, matched to PRL version in v2