Constraining the ionized gas evolution with CMB-spectroscopic survey cross-correlation

TL;DR

This paper forecasts how future CMB and galaxy surveys can precisely measure the evolution of ionized gas in the universe through tomographic cross-correlation techniques, improving constraints on gas models across cosmic time.

Contribution

It introduces a forecast method using tomographic cross-correlation between kSZ effect and galaxy surveys to constrain ionized gas evolution models with high precision.

Findings

Planck constrains constant $f_{gas}$ with ~0.2 error per redshift bin.

CMB-S4 can constrain $f_{gas}$ to ~10^{-3} accuracy.

CMB-S4 can measure the redshift evolution index $eta$ with $\sigma_eta o 0.01$--0.1.

Abstract

We forecast the prospective constraints on the ionized gas model $f_{\rm gas}(z)$ at different evolutionary epochs via the tomographic cross-correlation between kinetic Sunyaev-Zeldovich (kSZ) effect and the reconstructed momentum field at different redshifts. The experiments we consider are the Planck and CMB Stage-4 survey for CMB and the SDSS-III for the galaxy spectroscopic survey. We calculate the tomographic cross-correlation power spectrum, and use the Fisher matrix to forecast the detectability of different $f_{\rm gas}(z)$ models. We find that for constant $f_{\rm gas}$ model, Planck can constrain the error of $f_{\rm gas}$ ($\sigma_{f_{\rm gas}}$) at each redshift bin to $\sim 0.2$, whereas four cases of CMB-S4 can achieve $\sigma_{f_{\rm gas}} \sim 10^{-3}$. For $f_{\rm gas}(z)=f_{\rm gas,0}/(1+z)$ model the error budget will be slightly broadened. We also investigate the model $f_{\rm gas}(z)=f_{\rm gas,0}/(1+z)^{\alpha}$. Planck is unable to constrain the index of redshift evolution, but the CMB-S4 experiments can constrain the index $\alpha$ to the level of $\sigma_{\alpha} \sim 0.01$--$0.1$. The tomographic cross-correlation method will provide an accurate measurement of the ionized gas evolution at different epochs of the Universe.