An approach to cold dark matter deviation and the H0 tension problem by using machine learning

Abstract

In this work, two different models, one with cosmological constant , and baryonic and dark matter (with ωdm ≠ 0), and the other with an X dark energy (with ωde ≠ -1), and baryonic and dark matter (with ωdm ≠ 0), are investigated and compared. Using Bayesian machine learning analysis, constraints on the free parameters of both models are obtained for the three redshift ranges: z∈ [0,2], z∈ [0,2.5], and z∈ [0,5], respectively. For the first two redshift ranges, high-quality observations of the expansion rate H(z) exist already, and they are used for validating the fitting results. Additionally, the extended range z∈ [0,5] provides predictions of the model parameters, verified when reliable higher-redshift H(z) data are available. This learning procedure, based on the expansion rate data generated from the background dynamics of each model, shows that, at cosmological scales, there is a deviation from the cold dark matter paradigm, ωdm ≠ 0, for all three redshift ranges. The results show that this approach may qualify as a solution to the H0 tension problem. Indeed, it hints at how this issue could be effectively solved (or at least alleviated) in cosmological models with interacting dark energy.