Multiple kinetic k-essence, phantom barrier crossing and stability

TL;DR

This paper demonstrates that multiple kinetic k-essence models can cross the phantom divide line while maintaining stability, fitting observational data and avoiding superluminal issues.

Contribution

It introduces a stable multiple kinetic k-essence dark energy model that allows crossing of the phantom barrier without instabilities or superluminal propagation.

Findings

Model fits Supernova Ia data well

Dark energy crosses -1 at z ~ 0.2

Dark energy density tracks matter at high redshift

Abstract

We investigate models of dark energy with purely kinetic multiple k-essence sources that allow for the crossing of the phantom divide line, without violating the conditions of stability. It is known that with more than one kinetic k-field one can possibly construct dark energy models whose equation of state parameter $\wx$ crosses -1 (the phantom barrier) at recent red-shifts, as indicated by the Supernova Ia and other observational probes. However, such models may suffer from cosmological instabilities, as the effective speed of propagation $\cx$ of the dark energy density perturbations may become {\it imaginary} while the $\wx = -1$ barrier is crossed. Working out the expression for $\cx$ we show that multiple kinetic k-essence fields do indeed lead to a $\wx = -1$ crossing dark energy model, satisfying the stability criterion $\cx^2 \geq 0$ as well as the condition $\cx \leq 1$ (in natural units), which implies that the dark energy is not super-luminal. As a specific example, we construct a phantom barrier crossing model involving three k-fields for which $\cx$ is a constant, lying between 0 and 1. The model fits well with the latest Supernova Ia Union data, and the best fit shows that $\wx$ crosses -1 at red-shift $z \sim 0.2$, whereas the dark energy density nearly tracks the matter density at higher red-shifts.