Waveform models for the gravitational-wave memory effect: II. Time-domain and frequency-domain models for nonspinning binaries (2504.18635v1)

Abstract: The nonlinear gravitational-wave (GW) memory effect$\unicode{x2014}$a permanent shift in the GW strain that arises from nonlinear GW interactions in the wave zone$\unicode{x2014}$is a prediction of general relativity which has not yet been observed. The amplitude of the GW memory effect from binary-black-hole (BBH) mergers is small compared to that of primary (oscillatory) GWs and is unlikely to be detected by current ground-based detectors. Evidence for its presence in the population of all the BBH mergers is more likely, once thousands of detections are made by these detectors. Having an accurate and computationally efficient waveform model of the memory signal will assist detecting the memory effect with current data-analysis pipelines. In this paper, we build on our prior work to develop analytical time-domain and frequency-domain models for the dominant nonlinear memory multipole signal ($l=2$, $m=0$) from nonspinning BBH mergers in quasicircular orbits. The model is calibrated for mass ratios between one and eight. There are three parts to the time-domain signal model: a post-Newtonian inspiral, a quasinormal-mode-based ringdown, and a phenomenological signal during the late inspiral and merger (which interpolates between the inspiral and ringdown). The time-domain model also has an analytical Fourier transform, which we compute in this paper. We assess the accuracy of our model using the mismatch between our waveform model and the memory signal computed from the oscillatory modes of a numerical-relativity surrogate model. We use the advanced LIGO sensitivity curve from the fourth observing run and find that the mismatch increases with the total mass of the system and is of order $10^{-2}\unicode{x2013}10^{-4}$.