Dynamics of a Bianchi Type I Model With a Concave Potential

Abstract

In this paper, we study the dynamics of a Bianchi Type I potential in the presence of a concave potential of the form V(φ) = V0 [1- ( φμ)n], where V0 is a constant, and μ is a mass scale. We show that there are two classes of equilibrium points. The first class corresponds to φ ≠ 0, μ ≠ 0, n = 0, and φ = 0, which describe expanding and contracting de Sitter universes, for which the shear anisotropy is zero. We show that the expanding de Sitter universe is a local sink of the system, and therefore has associated to it a stable manifold. Thus, orbits will approach this point at late times. In other words, such a model is found to inflate and isotropize at late times as long as n = 0. The second class of equilibrium points corresponds to an expanding and contracting anisotropic universe. However, these points are found to emerge only when n > 1, φ = φ = 0, which importantly implies that V = V0 < 0 at this point in order to ensure that the square of the shear scalar, σ2 is real. Therefore, such equilibrium points correspond to the ekpyrotic cosmological models. Further, we show that for n = 2, by Lyapunov's stability theorem, the expanding equilibrium point is asymptotically stable, while for n > 2, a two-dimensional stable manifold exists corresponding to the fact that for n > 2, such an equilibrium point represents a local sink of the system. Finally, we give a general condition for inflation to occur in this model in terms of the deceleration parameter, and show that the expanding ekpyrotic equilibrium point undergoes the phenomenon of anisotropic inflation if -3/5 < V0 < 0, where > 0 is the cosmological constant.