Interferences in the Stochastic Gravitational Wave Background

TL;DR

This paper develops a time-dependent framework for analyzing the stochastic gravitational wave background, revealing oscillatory features and interference effects that can distinguish different cosmological sources.

Contribution

It introduces a non-stationary approach to SGWB analysis, deriving analytical expressions for waveform correlations and identifying unique interference patterns from various sources.

Findings

Oscillatory fine structure in strain power spectrum and energy density.

Interference effects from non-smooth, singular sources like cosmic strings.

Rescaled strain spectra can differ significantly from energy density predictions.

Abstract

Although the expansion of the Universe explicitly breaks the time-translation symmetry, cosmological predictions for the stochastic gravitational wave background (SGWB) are usually derived under the so-called stationary hypothesis. By dropping this assumption and keeping track of the time dependence of gravitational waves at all length scales, we derive the expected unequal-time (and equal-time) waveform of the SGWB generated by scaling sources, such as cosmic defects. For extinct and smooth enough sources, we show that all observable quantities are uniquely and analytically determined by the holomorphic Fourier transform of the anisotropic stress correlator. Both the strain power spectrum and the energy density parameter are shown to have an oscillatory fine structure, they significantly differ on large scales while running in phase opposition at large wavenumbers $k$. We then discuss scaling sources that are never extinct nor smooth and which generate a singular Fourier transform of the anisotropic stress correlator. For these, we find the appearance of interferences on top of the above-mentioned fine-structure as well as atypical behaviour at small scales. For instance, we expect the rescaled strain power spectrum $k^2 \mathcal{P}_h$ generated by long cosmic strings in the matter era to oscillate around a scale invariant plateau. These singular sources are also shown to produce orders of magnitude difference between the rescaled strain spectra and the energy density parameter suggesting that only the former should be used for making reliable observable predictions. Finally, we discuss how measuring such a fine structure in the SGWB could disambiguate the possible cosmological sources.