Litcius/Paper detail

Gravitational memory: new results from post-Newtonian and self-force theory

Kevin Cunningham, Chris Kavanagh, Adam Pound, David Trestini, Niels Warburton, Jakob Neef

2025Classical and Quantum Gravity11 citationsDOIOpen Access PDF

Abstract

Abstract We compute the (displacement) gravitational wave memory due to a quasi-circular inspiral of two black holes using a variety of perturbative techniques. Within post-Newtonian theory, we extend previous results for non-spinning compact binaries to 3.5PN order. Using the gravitational self-force approach, we compute the memory at first order in the mass ratio for inspirals into a Kerr black hole. We do this both numerically and via a double post-Newtonian–self-force expansion which we carry out to 5PN order. At second order in the self-force approach, near-zone calculations encounter an infrared divergence associated with memory, which is resolved through matching the near-zone solution to a post-Minkowskian expansion in the far zone. We describe that matching procedure for the first time and show how it introduces nonlocal-in-time memory effects into the two-body dynamics at second order in the mass ratio, as was also predicted by recent 5PN calculations within the effective field theory approach. We then compute the gravitational-wave memory through second order in the mass ratio (excluding certain possible memory distortion effects) and find that it agrees well with recent results from numerical relativity simulations for near-comparable-mass binaries.

Topics & Concepts

PhysicsNewtonian fluidGravitationClassical mechanicsGravitational forceTheoretical physicsMathematical physicsBiofield Effects and BiophysicsEarth Systems and Cosmic Evolution
Gravitational memory: new results from post-Newtonian and self-force theory | Litcius