Cosmographic view on the H0 and σ8 tensions

Abstract

Measurements of the H0 and σ8 parameters within the standard cosmological model recently highlighted significant statistical tensions between the cosmic microwave background and low-redshift probes, such as local distance ladder, weak lensing and galaxy clustering surveys. In this work, we frame geometrical distances in a model-independent way by means of cosmographic approximations in the range z ∈ (0, 2.3) to take into account a robust dataset composed of Baryon Acoustic Oscillations (BAO), type Ia Supernovae (SN), Cosmic Chronometer (CC) data, and measurements from Redshift Space Distortions (RSD). From the joint analysis BAO\,+\,SN\,+\,CC\,+\,RSD, we find an accuracy of 1.4\% and 3.7\% on H0 and σ8, respectively. Our result for H0 is at 2σ tension with local measurements by the SH0ES team, while our σ8 estimate is at 2.6σ tension with Planck-CMB analysis. This inference shows a tension statistically smaller when compared to those estimated via the model. We also find that the jerk parameter can deviate more than 3σ from the prediction. Under the same cosmographic setup, we also present results by considering a SH0ES Gaussian prior on H0 that allows for improved accuracy of the parameter space of the models. The present work brings observational constraints on H0 and σ8 into a new model-independent perspective, which differs from the predictions obtained within the paradigm.