Wave-optics limit of the stochastic gravitational wave background

TL;DR

This paper develops a wave-optics formalism for the stochastic gravitational wave background, capturing interference effects and polarization modulations caused by cosmic structures, beyond the geometric optics approximation.

Contribution

It introduces a wave-optics based theoretical framework for the SGWB that includes polarization effects and anisotropies, extending previous geometric optics approaches.

Findings

Interaction with matter modulates SGWB intensity.

No net polarization difference for unpolarized, Gaussian backgrounds.

Hexadecapole anisotropy needed for tensor polarization modes.

Abstract

The stochastic gravitational wave background (SGWB) is a rich resource of cosmological information, encoded both in its source statistics and anisotropies induced by propagation effects. We provide a theoretical description of it, without employing theoretical tools which rely on the geometric optics limit. Our formalism is based on the so-called {\it classical matter approximation} and it is able to capture wave-optics effects, such as interference and diffraction. We show that the interaction between the gravitational waves and the cosmic structures along the line-of-sight produce observable scalar and vector polarization modes, on top of modulating the tensorial ones. We build the two point correlation function describing the statistics of the SGWB, and introduce the intensity and gravitational Stokes parameters for all its components. In the case of an unpolarized, Gaussian and statistically homogeneous SGWB, we show that the interaction with matter modulates its intensity and does not generate a net difference between left- and right- helicity tensor and vector modes, as expected. We demonstrate that, in order to produce $Q_T$- and $U_T$- tensor polarization modes the background must posses an hexadecapole anisotropy, while a quandrupole anisotropy can source the vector $Q_V$- and $U_V$- Stokes parameters.