Slow-roll inflation from a geometric scalar-tensor model with self-interacting potentials

Abstract

We consider slow-roll inflation in the context of a modified Brans-Dicke dilaton gravity. From a two self-interacting potentials V(φ), we reproduce a Starobinsky-like potential and, commonly in syperstring models, an exponential tail potential V(φ)(1-eα0φ), with α0 being a constant coefficient related to the Brans-Dicke parameter ω. Using the observational bounds on the spectral index ns and tensor-to-scalar ratio r imposed by Planck-CMB baseline data and the BICEP2/Keck collaboration with combination with Planck 2018 and the Baryonic Acoustic Oscillations(BAO), we obtain for both models a good agreement with current observations with ns = 0.960 - 0.972 and r<0.02. In addition, the resulting large values of ω suggests a possible linkage of the inflationary regime and today's solar system bounds.