Dark energy from a quintessence (phantom) field rolling near potential minimum (maximum)

Abstract

We examine dark energy models in which a quintessence or a phantom field, φ, rolls near the vicinity of a local minimum or maximum, respectively, of its potential V(φ). Under the approximation that (1/V)(dV/dφ) 1, [although (1/V)(d2 V/dφ2) can be large], we derive a general expression for the equation of state parameter w as a function of the scale factor for these models. The dynamics of the field depends on the value of (1/V)(d2 V/dφ2) near the extremum, which describes the potential curvature. For quintessence models, when (1/V)(d2 V/dφ2)<3/4 at the potential minimum, the equation of state parameter w(a) evolves monotonically, while for (1/V)(d2 V/dφ2)>3/4, w(a) has oscillatory behavior. For phantom fields, the dividing line between these two types of behavior is at (1/V)(d2 V/dφ2) = -3/4. Our analytical expressions agree within 1% with the exact (numerically-derived) behavior, for all of the particular cases examined, for both quintessence and phantom fields. We present observational constraints on these models.