Inferring S8(z) and γ(z) with cosmic growth rate measurements using machine learning

Abstract

Measurements of the cosmological parameter S8 provided by cosmic microwave background and large scale structure data reveal some tension between them, suggesting that the clustering features of matter in these early and late cosmological tracers could be different. In this work, we use a supervised learning method designed to solve Bayesian approach to regression, known as Gaussian Processes regression, to quantify the cosmic evolution of S8 up to z 1.5. For this, we propose a novel approach to find firstly the evolution of the function σ8(z), then we find the function S8(z). As a sub-product we obtain a minimal cosmological model-dependent σ8(z=0) and S8(z=0) estimates. We select independent data measurements of the growth rate f(z) and of [fσ8](z) according to criteria of non-correlated data, then we perform the Gaussian reconstruction of these data sets to obtain the cosmic evolution of σ8(z), S8(z), and the growth index γ(z). Our statistical analyses show that S8(z) is compatible with Planck cosmology; when evaluated at the present time we find σ8(z=0) = 0.766 0.116 and S8(z=0) = 0.732 0.115. Applying our methodology to the growth index, we find γ(z=0) = 0.465 0.140. Moreover, we compare our results with others recently obtained in the literature. In none of these functions, i.e. σ8(z), S8(z), and γ(z), do we find significant deviations from the standard cosmology predictions.