Constraints on Steep Equation of State for the Dark Energy using BAO

Abstract

We present a parametrization for the Dark Energy Equation of State "EoS" which has a rich structure. Our EoS has a transition at pivotal redshift zT between the present day value w0 to an early time wi=wa+w0 w(z>>0) and the steepness of this transition is given in terms of the q parameter. The proposed parametrization is w=w0+wa(z/zT)q/(1+(z/zT))q, with w0, wi, q and zT constant parameters. This transition is motivated by scalar field dynamics such as for example quintessence models. Our parametrization reduces to the widely used EoS w=w0+wa(1-a) for zT=q=1. We study if a late time transition is favored by BAO measurements and Planck priors. According to our results, an EoS with a present value of w0 = -0.91 and a high redshifts value wi =-0.62, featuring a transition at a redshift of zT = 1.16 with an exponent q = 9.95 is a good fit to the observational data. We found good agreement between the model and the data reported by the different surveys. A "thawing" dynamics is preferred by the use of BAO data alone (including Lymman-α forest measurements) and a "freezing" evolution of the EoS is preferred when we include the priors from Planck. The constraints imposed by the available BAO measurements (Beutler:2011hx, Ross:2014qpa, Anderson:2013oza, Kazin:2014qga, Font-Ribera:2013wce, Delubac:2014aqe, Gong:2015tta) and its physical behavior are discussed.