Generalising Axion-like particle as the curvaton: sourcing primordial density perturbation and non-Gaussianities

Abstract

We investigate the non-perturbatively generated axion-like particle (ALP) potential, involving fermions in the dark sector that couple to the ALP, in an early cosmological inflationary stage with the ALP being a spectator field. The potential here deviates from the standard cosine nature due to the presence of the two fermion masses mu and md which couple to the ALP. The ALP is a spectator field during inflation but it starts to oscillate and dominates the energy density of the universe after inflation ends, thereby sourcing isocurvature perturbations, while standard curvature fluctuations form the inflaton are assumed to be sub-dominant. Subsequently the ALP decays converting the isocurvature perturbations to adiabatic perturbations thereby acting as the origin of the primordial density perturbations. We identify the parameter space involving the axion decay constant fa, scale of confinement , ALP mass m and the masses of the fermions, mu and md where it can satisfactorily behave as the curvaton and source the observed primordial density perturbation. We also predict local non-Gaussianity signals for bi-spectrum and tri-spectrum fNL and gNL, as a function of the ratio mu/md, which are within the allowed range in the latest Planck observations and are detectable with future observations. Particularly we observed that the value of fNL and gNL are dependent on the ratio of mu and md: fNL is more or less positive for all scenarios except mu = md and gNL is always positive irrespective of the ratio between mu and md. The results of our analysis in the limit mu = md resembles vanilla curvaton scenario while in the limit mu md resembles pure axion cosine potential.