Asymptotics of Bianchi IX under the presence of matter: approximate Kasner map

TL;DR

This paper analyzes how matter fields influence the asymptotic behavior of Bianchi IX cosmology near singularities, deriving an approximate Kasner map that accounts for matter effects and impacts the model's chaotic dynamics.

Contribution

It provides an approximate analytic solution for Bianchi IX dynamics with matter and explicitly derives the Kasner map including matter effects, highlighting their influence on the system's chaos.

Findings

Matter reduces the deflection angle post-bounce compared to vacuum cases.

Presence of matter increases the convexity of potential walls.

Matter effects may alter the chaotic behavior near singularities.

Abstract

The goal of this paper is to analyze the effects of the matter fields in the evolution of the Bianchi IX cosmology close to the singularity. Although the dynamics of this model is very involved, asymptotically, as the singularity is approached, it can be well approximated as a succession of Bianchi I periods connected by quick bounces against potential walls. Moreover, in such limit, matter fields (excluding stiff matter) are known to be subdominant with respect to the anisotropies. Therefore, by performing an expansion around small volumes, and assuming that the dominant matter contribution in this regime can be described as a barotropic perfect fluid with a linear equation of state, we obtain an approximate analytic solution of the dynamics. Then, we explicitly compute the form of the transition (Kasner) map that relates the pre- and post-bounce Bianchi I periods including the leading matter effects. As an important conclusion, we observe that generically the presence of matter leads to a post-bounce velocity with a lower deflection angle than in the vacuum case, and thus effectively increases the convex curvature of the potential walls. This effect may have important consequences in the chaotic nature of general relativity near spacelike singularities.