Evaluating extensions to LCDM: an application of Bayesian model averaging and selection

Abstract

We employ Bayesian Model Averaging (BMA) as a powerful statistical framework to address key cosmological questions about the universe's fundamental properties. We explore extensions beyond the standard model, considering a varying curvature density parameter k, a spectral index n s=1 and a varying n run, a constant dark energy equation of state (EOS) w0CDM and a time-dependent one w0waCDM. We also test cosmological data against a varying effective number of neutrino species N eff. Data from different combinations of cosmic microwave background (CMB) data from the last Planck PR4 analysis, CMB lensing from Planck 2018, baryonic acoustic oscillations (BAO) and the Bicep-KECK 2018 results, are used. We find that the standard model is favoured when combining CMB data with CMB lensing, BAO and Bicep-KECK 2018 data against K- model N eff- with a probability > 80\%. When investigating the dark energy EOS, we find that this dataset is not able to express a strong preference between the standard model and the constant dark energy EOS model w0CDM, with an approximately split model posterior probability of ≈ 60\%:40\% in favour of , whereas the time-varying dark energy EOS model is ruled out. Finally, we find that the CMB data alone show a strong preference for a model that includes the running of the spectral index n run, with a probability ≈ 90\%, when compared to the n s=1 model and the standard . Overall, we find that including the model uncertainty in the considered cases does not significantly impact the Hubble tension.