Gravitational waves from self-ordering scalar fields

TL;DR

This paper studies the gravitational wave spectrum produced by self-ordering scalar fields in the early universe, revealing conditions under which the spectrum is detectable and can compete with inflationary backgrounds.

Contribution

It provides a detailed analysis of the shape and amplitude of superhorizon gravitational wave spectra from scalar fields, highlighting their potential observability.

Findings

Spectrum is proportional to f^3 if source acts briefly.

Longer source activity yields a scale-invariant spectrum.

Amplitude could be detectable by BBO, LIGO, and LISA.

Abstract

Gravitational waves were copiously produced in the early Universe whenever the processes taking place were sufficiently violent. The spectra of several of these gravitational wave backgrounds on subhorizon scales have been extensively studied in the literature. In this paper we analyze the shape and amplitude of the gravitational wave spectrum on scales which are superhorizon at the time of production. Such gravitational waves are expected from the self ordering of randomly oriented scalar fields which can be present during a thermal phase transition or during preheating after hybrid inflation. We find that, if the gravitational wave source acts only during a small fraction of the Hubble time, the gravitational wave spectrum at frequencies lower than the expansion rate at the time of production behaves as $\Omega_{\rm GW}(f) \propto f^3$ with an amplitude much too small to be observable by gravitational wave observatories like LIGO, LISA or BBO. On the other hand, if the source is active for a much longer time, until a given mode which is initially superhorizon ($k\eta_* \ll 1$), enters the horizon, for $k\eta \gtrsim 1$, we find that the gravitational wave energy density is frequency independent, i.e. scale invariant. Moreover, its amplitude for a GUT scale scenario turns out to be within the range and sensitivity of BBO and marginally detectable by LIGO and LISA. This new gravitational wave background can compete with the one generated during inflation, and distinguishing both may require extra information.