Isocurvature modes and Baryon Acoustic Oscillations II: gains from combining CMB and Large Scale Structure

TL;DR

Combining CMB and Large Scale Structure data significantly reduces biases and improves constraints on isocurvature modes and cosmological parameters, even with complex models including curvature and dark energy variations.

Contribution

This study demonstrates that joint analysis of CMB and LSS data effectively breaks degeneracies and minimizes biases in estimating isocurvature contributions in complex cosmological models.

Findings

Joint analysis reduces systematic biases from isocurvature assumptions.

CMB and LSS combination achieves a small error of σ(f_iso) ~ 0.008.

Results highlight the synergy and potential of future galaxy surveys.

Abstract

We consider cosmological parameters estimation in the presence of a non-zero isocurvature contribution in the primordial perturbations. A previous analysis showed that even a tiny amount of isocurvature perturbation, if not accounted for, could affect standard rulers calibration from Cosmic Microwave Background observations such as those provided by the Planck mission, affect Baryon Acoustic Oscillations interpretation and introduce biases in the recovered dark energy properties that are larger than forecasted statistical errors from future surveys. Extending on this work, here we adopt a general fiducial cosmology which includes a varying dark energy equation of state parameter and curvature. Beside Baryon Acoustic Oscillations measurements, we include the information from the shape of the galaxy power spectrum and consider a joint analysis of a Planck-like Cosmic Microwave Background probe and a future, space-based, Large Scale Structure probe not too dissimilar from recently proposed surveys. We find that this allows one to break the degeneracies that affect the Cosmic Microwave Background and Baryon Acoustic Oscillations combination. As a result, most of the cosmological parameter systematic biases arising from an incorrect assumption on the isocurvature fraction parameter $f_{iso}$, become negligible with respect to the statistical errors. We find that the Cosmic Microwave Background and Large Scale Structure combination gives a statistical error $\sigma(f_{iso}) \sim 0.008$, even when curvature and a varying dark energy equation of state are included, which is smaller than the error obtained from Cosmic Microwave Background alone when flatness and cosmological constant are assumed. These results confirm the synergy and complementarity between Cosmic Microwave Background and Large Scale Structure, and the great potential of future and planned galaxy surveys.