Cosmological models with arbitrary spatial curvature in the theory of gravity with non-minimal derivative coupling

Abstract

We investigate isotropic and homogeneous cosmological scenarios in the scalar-tensor theory of gravity with non-minimal derivative coupling of a scalar field to the curvature given by the term (ζ/H02) Gμ∇μφ ∇φ in the Lagrangian. In general, a cosmological model is determined by six dimensionless parameters: the coupling parameter ζ, and density parameters 0 (cosmological constant), 2 (spatial curvature term), 3 (non-relativistic matter), 4 (radiation), 6 (scalar field term), and the universe evolution is described by the modified Friedmann equation. In the case ζ=0 (no non-minimal derivative coupling) and 6=0 (no scalar field) one has the standard -model, while if 6=0 -- the -model with an ordinary scalar field. The situation is crucially changed when the scalar field possesses non-minimal derivative coupling to the curvature, i.e. when ζ=0. Now, depending on model parameters, (i) There are three qualitatively different initial state of the universe: an eternal kinetic inflation, an initial singularity, and a bounce. The bounce is possible for all types of spatial geometry of the homogeneous universe; (ii) For all types of spatial geometry, the universe goes inevitably through the primary quasi-de Sitter (inflationary) epoch when a(t) ehdS(H0t) with the de Sitter parameter hdS2=1/9ζ-8ζ23/276. The mechanism of primary or kinetic inflation is provided by non-minimal derivative coupling and needs no fine-tuned potential; (iii) There are cyclic scenarios of the universe evolution with the non-singular bounce at a minimal value of the scale factor, and a turning point at the maximal one; (iv) There is a natural mechanism providing a change of cosmological epochs.