The Asymptotic Behaviour of Cosmological Models Containing Matter and Scalar Fields

TL;DR

This paper analyzes the long-term behavior of scalar field cosmological models using dynamical systems theory, addressing issues like isotropization and inflation in both general relativistic and string cosmologies.

Contribution

It provides new insights into the stability, isotropization, and inflationary behavior of scalar field cosmological models, including the effects of curvature, interactions, and cosmological constants.

Findings

Matter scaling solutions are unstable to curvature perturbations.

Some models isotropize and address the isotropy problem.

Presence of a positive cosmological constant can lead to multi-bouncing universes.

Abstract

The asymptotic behaviour of two classes of scalar field cosmological models are studied using the theory of dynamical systems: general relativistic Bianchi models containing matter and a scalar field with an exponential potential and a class of spatially homogeneous string cosmological models. The purpose of this thesis is to examine some of the outstanding problems which currently exist in cosmology, particularly regarding isotropization and inflation. It is shown that the matter scaling solutions are unstable to curvature perturbations. It is then shown that the Bianchi class B exponential potential models can alleviate the isotropy problem; an open set of models within this class do isotropize to the future. It is also shown that the presence of an interaction term in the subclass of isotropic models can lead to inflationary models with late-time oscillatory behaviour in which the matter is not driven to zero. Next, within the class of the string cosmologies studied, it is shown that there is a subclass which do not inflate at late times in the post-big bang regime. Furthermore, all string models studied typically do not have a late--time flatness problem. Indeed, it is shown that curvature typically plays an important r\^{o}le only at intermediate times in most models. It is also shown that the presence of a positive cosmological constant in the models studied can lead to interesting physical behaviour, such as multi-bouncing universes. A mathematical equivalence between general relativistic scalar field theories and scalar-tensor theories and string theories has been extensively exploited and thus the results obtained from the string analysis compliment the results obtained from the Bianchi class B exponential potential analysis.