Signatures of the neutrino thermal history in the spectrum of primordial gravitational waves

TL;DR

This paper investigates how neutrino anisotropic stress affects primordial gravitational waves, revealing potential spectral features linked to the Universe's thermal history, observable by Pulsar Timing Arrays.

Contribution

It provides a detailed analysis of neutrino-induced damping of gravitational waves, including effects of collisions and thermal history events, extending previous studies.

Findings

22% wave absorption by standard neutrinos

Maximum 43% absorption in ultrarelativistic case

Spectral features from neutrino decoupling and e+e- annihilation

Abstract

In this paper we study the effect of the anisotropic stress generated by neutrinos on the propagation of primordial cosmological gravitational waves. The presence of anisotropic stress, like the one generated by free-streaming neutrinos, partially absorbs the gravitational waves (GWs) propagating across the Universe. We find that in the standard case of three neutrino families, 22% of the intensity of the wave is absorbed, in fair agreement with previous studies. We have also calculated the maximum possible amount of damping, corresponding to the case of a flat Universe completely dominated by ultrarelativistic collisionless particles. In this case 43% of the intensity of the wave is absorbed. Finally, we have taken into account the effect of collisions, using a simple form for the collision term parameterized by the mean time between interactions, that allows to go smoothly from the case of a tigthly-coupled fluid to that of a collisionless gas. The dependence of the absorption on the neutrino energy density and on the effectiveness of the interactions opens the interesting possibility of observing spectral features related to particular events in the thermal history of the Universe, like neutrino decoupling and electron-positron annihilation, both occurring at T~1 MeV. GWs entering the horizon at that time will have today a frequency $\nu\sim 10^{-9} \Hz$, a region that is going to be probed by Pulsar Timing Arrays.