Data-constrained reionization and its effects on cosmological parameters

TL;DR

This paper analyzes how incorporating astrophysical reionization data into CMB analysis affects the estimation of cosmological parameters, revealing significant shifts in key values and constraints.

Contribution

It introduces a method combining CMB data with astrophysical reionization constraints, jointly varying cosmological and astrophysical parameters for more accurate results.

Findings

Reionization history impacts cosmological parameter estimates.

The scalar spectral index n_s is constrained away from 1 at >3σ.

Optical depth τ_e is significantly decreased.

Abstract

We perform an analysis of the recent WMAP7 data considering physically motivated and viable reionization scenarios with the aim of assessing their effects on cosmological parameter determinations. The main novelties are: (i) the combination of CMB data with astrophysical results from quasar absorption line experiments; (ii) the joint variation of both the cosmological and astrophysical [governing the evolution of the free electron fraction x_e(z)] parameters. Including a realistic, data-constrained reionization history in the analysis induces appreciable changes in the cosmological parameter values deduced through a standard WMAP7 analysis. Particularly noteworthy are the variations in Omega_bh^2 = 0.02258^{+0.00057}_{-0.00056} (WMAP7) vs. Omega_bh^2$ = 0.02183\pm 0.00054 (WMAP7 + ASTRO), and the new constraints for the scalar spectral index, for which WMAP7 + ASTRO excludes the Harrison-Zel'dovich value n_s=1 at more than 3\sigma. Finally, the e.s. optical depth value is considerably decreased with respect to the standard WMAP7, i.e. \tau_{e}=0.080\pm 0.012. We conclude that the inclusion of astrophysical datasets, allowing to robustly constrain the reionization history, in the extraction procedure of cosmological parameters leads to relatively important differences in the final determination of their values.