Tomographic constraints on the production rate of gravitational waves from astrophysical sources

TL;DR

This paper uses cross-correlation of gravitational wave maps and galaxy data to constrain the rate of gravitational wave production over cosmic time, setting limits that future experiments could improve.

Contribution

It introduces a tomographic cross-correlation method to constrain the astrophysical gravitational wave production rate density as a function of redshift.

Findings

No significant cross-correlation detected.

Constraints on gravitational wave production rate vary with redshift.

Future experiments could detect the signal.

Abstract

Using an optimal quadratic estimator, we measure the large-scale cross-correlation between maps of the stochastic gravitational-wave intensity, constructed from the first three LIGO-Virgo observing runs, and a suite of tomographic samples of galaxies covering the redshift range $z\lesssim 2$. We do not detect any statistically significant cross-correlation, but the tomographic nature of the data allows us to place constraints on the (bias-weighted) production rate density of gravitational waves by astrophysical sources as a function of cosmic time. Our constraints range from $\langle b\dot{\Omega}_{\rm GW}\rangle<3.0\times10^{-9}\,{\rm Gyr}^{-1}$ at $z\sim0.06$ to $\langle b\dot{\Omega}_{\rm GW}\rangle<2.7\times10^{-7}\,{\rm Gyr}^{-1}$ at $z\sim1.5$ (95\% C.L.), assuming a frequency spectrum of the form $f^{2/3}$ (corresponding to an astrophysical background of binary mergers), and a reference frequency $f_{\rm ref}=25\,{\rm Hz}$. Although these constraints are $\sim2$ orders of magnitude higher than the expected signal, we show that a detection may be possible with future experiments.