Observational constraints on conformal time symmetry, missing matter and double dark energy

Abstract

The current concordance model of cosmology is dominated by two mysterious ingredients: dark matter and dark energy. In this paper, we explore the possibility that, in fact, there exist two dark-energy components: the cosmological constant , with equation-of-state parameter w=-1, and a `missing matter' component X with wX=-2/3, which we introduce here to allow the evolution of the universal scale factor as a function of conformal time to exhibit a symmetry that relates the big bang to the future conformal singularity, such as in Penrose's conformal cyclic cosmology. Using recent cosmological observations, we constrain the present-day energy density of missing matter to be X,0=-0.034 0.075. This is consistent with the standard model, but constraints on the energy densities of all the components are considerably broadened by the introduction of missing matter; significant relative probability exists even for X,0 0.1, and so the presence of a missing matter component cannot be ruled out. As a result, a Bayesian model selection analysis only slightly disfavours its introduction by 1.1 log-units of evidence. Foregoing our symmetry requirement on the conformal time evolution of the universe, we extend our analysis by allowing wX to be a free parameter. For this more generic `double dark energy' model, we find wX = -1.01 0.16 and X,0 = -0.10 0.56, which is again consistent with the standard model, although once more the posterior distributions are sufficiently broad that the existence of a second dark-energy component cannot be ruled out. The model including the second dark energy component also has an equivalent Bayesian evidence to , within the estimation error, and is indistinguishable according to the Jeffreys guideline.