Kination cosmology from scalar fields and gravitational-wave signatures

TL;DR

This paper explores a late-occurring kination era driven by scalar fields, analyzing its impact on primordial gravitational waves and proposing it as an observable signature for axion models and early universe physics.

Contribution

It introduces the concept of a late kination era within the Standard Model radiation epoch and studies its distinctive gravitational-wave signatures and implications for axion dark matter and baryogenesis.

Findings

Distinctive peaked gravitational-wave spectra predicted

Detectability prospects at SKA, LIGO, LISA, ET, CE, BBO analyzed

Links between gravitational waves and axion parameters established

Abstract

Kination denotes an era in the cosmological history corresponding to an equation of state $\omega=+1$ such that the total energy density of the universe redshifts as the sixth inverse power of the scale factor. This arises if the universe is dominated by the kinetic energy of a scalar field. It has often been motivated in the literature as an era following inflation, taking place before the radiation era. In this paper, we review instead the possibility that kination is disconnected from primordial inflation and occurs much later, inside the Standard Model radiation era. We study the implications on all main sources of primordial gravitational waves. We show how this leads to very distinctive peaked spectra in the stochastic background of long-lasting cosmological sources of gravitational waves, namely the irreducible gravitational waves from inflation, and gravitational waves from cosmic strings, both local and global, with promising observational prospects. We present model-independent signatures and detectability predictions at SKA, LIGO, LISA, ET, CE, BBO, as a function of the energy scale and duration of the kination era. We then argue that such intermediate kination era is in fact symptomatic in a large class of axion models. We analyse in details the scalar field dynamics, the working conditions and constraints in the underlying models. We present the gravitational-wave predictions as a function of particle physics parameters. We derive the general relation between the gravitational-wave signal and the axion dark matter abundance as well as the baryon asymmetry. We investigate the predictions for the special case of the QCD axion. The key message is that gravitational-waves of primordial origin represent an alternative experimental probe of axion models.