A cosmological model describing the early inflation, the intermediate decelerating expansion, and the late accelerating expansion by a quadratic equation of state

Abstract

We develop a cosmological model based on a quadratic equation of state p/c2=-(α+1)2/P+α-(α+1) (where P is the Planck density and the cosmological density) "unifying" vacuum energy and dark energy in the spirit of a generalized Chaplygin gas model. For → P, it reduces to p=- c2 leading to a phase of early accelerated expansion (early inflation) with a constant density equal to the Planck density P (vacuum energy). For P, we recover the standard linear equation of state p=α c2 describing radiation (α=1/3) or pressureless matter (α=0) and leading to an intermediate phase of decelerating expansion. For → , we get p=- c2 leading to a phase of late accelerated expansion (late inflation) with a constant density equal to the cosmological density (dark energy). We show a nice symmetry between the early universe (vacuum energy + α-fluid) and the late universe (α-fluid + dark energy). In our model, they are described by two polytropic equations of state with index n=+1 and n=-1 respectively. Furthermore, the Planck density P in the early universe plays a role similar to the cosmological density in the late universe. They represent fundamental upper and lower density bounds differing by 122 orders of magnitude. This quadratic equation of state leads to a fully analytical model describing the evolution of the universe from the early inflation (Planck era) to the late accelerated expansion (de Sitter era). These two phases are bridged by a decelerating algebraic expansion (α-era). This model does not present any singularity at t=0 and exists eternally in the past. It admits a scalar field interpretation based on a quintessence field or a tachyon field.