Statistics of Thawing K-essence Dark Energy Models

Abstract

K-essence is a minimally-coupled scalar field whose Lagrangian density L is a function of the field value φ and the kinetic energy X=12∂μφ∂μφ. In the thawing scenario, the scalar field is frozen by the large Hubble friction in the early universe, and therefore initial conditions are specified. We construct thawing k-essence models by generating Taylor expansion coefficients of L(φ, X) from random matrices. From the ensemble of randomly generated thawing k-essence models, we select dark energy candidates by assuming negative pressure and non-growth of sub-horizon inhomogeneities. For each candidate model the dark energy equation of state function is fit to the Chevallier-Polarski-Linder parameterization w(a) ≈ w0+wa(1-a), where a is the scale factor. The thawing k-essence dark models distribute very non-uniformly in the (w0, wa) space. About 90\% models cluster in a narrow band in the proximity of a slow-roll line wa≈ -1.42 (m0.3)0.64(1+w0), where m is the present matter density fraction. This work is a proof of concept that for a certain class of models very non-uniform theoretical prior on (w0, wa) can be obtained to improve the statistics of model selection.