Inflation and Dark Energy from a Scalar Field in Supergravity

Abstract

In this paper we present a model for accelerated expansion of the universe, both during inflation and the present stage of the expansion, from four dimensional N=1 supergravity. We evaluate the tensor-to-scalar ratio (r≈ 0.00034), the scalar spectral index (ns≈ 0.970) and the running spetral index (dns/dk≈ -6×10-5), and we notice that these parameters are in agreement with Planck+WP+lensing data and with BICEP2/Keck and Planck joint analysis, at 95\% CL. The number of e-folds is 50 or higher. The reheating period has an associated temperature TR1012 GeV, which agrees with the one required by thermal leptogenesis. Regarding the scalar field as dark energy, the autonomous system for it in the presence of a barotropic fluid provides a stable fixed point that leads to a late-time accelerated expansion of the universe, with an equation of state that mimics the cosmological constant (w≈ -0.997).