Dynamics and cosmological constraints on Brans-Dicke cosmology

Abstract

We investigate observational constraints on the Brans-Dicke cosmological model using observational data coming from distant supernovae type Ia, the Hubble function H(z) measurements, information coming from the Alcock-Paczy\'nski test, and baryon acoustic oscillations. Our analysis is based on the modified Friedmann function resulting form dynamical investigations of Brans-Dicke cosmology in the vicinity of a de Sitter state. The qualitative theory of dynamical systems enables us to obtain three different behaviors in the vicinity of this state. We find for a linear approach to the de Sitter state ωBD=-0.8606+0.8281-0.1341, for an oscillatory approach to the de Sitter state ωBD=-1.1103+0.1872-0.1729, and for the transient de Sitter state represented by a saddle-type critical point ωBD=-2.3837+0.4588-4.5459. We obtain the mass of the Brans-Dicke scalar field at the present epoch as mφ H0. The Bayesian methods of model comparison are used to discriminate between obtained models. We show that observational data point toward vales of the ωBD parameter close to the value suggested by the low-energy limit of the bosonic string theory.