Scaling Dark Energy in a Five-Dimensional Bouncing Cosmological Model
Abstract
We consider a 5-dimensional Ricci flat bouncing cosmological model in which the 4-dimensional induced matter contains two components at late times - the cold dark matter (CDM)+baryons and dark energy. We find that the arbitrary function f(z) contained in the solution plays a similar role as the potential V(φ) in quintessence and phantom dark energy models. To resolve the coincidence problem, it is generally believed that there is a scaling stage in the evolution of the universe. We analyze the condition for this stage and show that a hyperbolic form of the function f(z) can work well in this property. We find that during the scaling stage (before z≈ 2), the dark energy behaves like (but not identical to) a cold dark matter with an adiabatic sound speed cs2≈ 0 and px≈ 0. After z≈ 2, the pressure of dark energy becomes negative. The transition from deceleration to acceleration happens at zT≈ 0.8 which, as well as other predictions of the 5D model, agree with current observations.
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