On solving dynamical equations in general homogeneous isotropic cosmologies with scalaron

Abstract

We study general dynamical equations describing homogeneous isotropic cosmologies coupled to a scalaron . For flat cosmologies (k=0), we analyze in detail the gauge-independent equation describing the differential, (α)(α), of the map of the metric α to the scalaron field , which is the main mathematical characteristic locally defining a `portrait' of a cosmology in `α-version'. In the `-version', a similar equation for the differential of the inverse map, () -1(α), can be solved asymptotically or for some `integrable' scalaron potentials v(). In the flat case, () and (α) satisfy the first-order differential equations depending only on the logarithmic derivative of the potential. Once we know a general analytic solution for one of these -functions, we can explicitly derive all characteristics of the cosmological model. In the α-version, the whole dynamical system is integrable for k≠ 0 and with any `α-potential', v(α) v[(α)], replacing v(). There is no a priori relation between the two potentials before deriving or , which implicitly depend on the potential itself, but relations between the two pictures can be found by asymptotic expansions or by inflationary perturbation theory. Explicit applications of the results to a more rigorous treatment of the chaotic inflation models and to their comparison with the ekpyrotic-bouncing ones are outlined in the frame of our `α-formulation' of isotropic scalaron cosmologies. In particular, we establish an inflationary perturbation expansion for . When all the conditions for inflation are satisfied and obeys a certain boundary (initial) condition, we get the standard inflationary parameters, with higher-order corrections.