Cosmological Parameters Degeneracies and Non-Gaussian Halo Bias

TL;DR

This paper investigates how uncertainties in cosmological parameters affect measurements of primordial non-Gaussianity via halo bias, showing that future large-scale surveys can constrain $f_{NL}$ with high precision despite these uncertainties.

Contribution

It provides forecasts on the robustness of $f_{NL}$ measurements against cosmological parameter uncertainties for upcoming galaxy surveys.

Findings

Uncertainty in cosmological parameters increases $f_{NL}$ error by 10-30%.

Simultaneous constraints on $N_ u^{rel}$ significantly increase $f_{NL}$ error by ~80%.

Future surveys can measure $f_{NL}$ with a 1-$\sigma$ error of 2-5, competitive with CMB bispectrum constraints.

Abstract

We study the impact of the cosmological parameters uncertainties on the measurements of primordial non-Gaussianity through the large-scale non-Gaussian halo bias effect. While this is not expected to be an issue for the standard LCDM model, it may not be the case for more general models that modify the large-scale shape of the power spectrum. We consider the so-called local non-Gaussianity model and forecasts from planned surveys, alone and combined with a Planck CMB prior. In particular, we consider EUCLID- and LSST-like surveys and forecast the correlations among $f_{\rm NL}$ and the running of the spectral index $\alpha_s$, the dark energy equation of state $w$, the effective sound speed of dark energy perturbations $c^2_s$, the total mass of massive neutrinos $M_\nu=\sum m_\nu$, and the number of extra relativistic degrees of freedom $N_\nu^{rel}$. Neglecting CMB information on $f_{\rm NL}$ and scales $k > 0.03 h$/Mpc, we find that, if $N_\nu^{\rm rel}$ is assumed to be known, the uncertainty on cosmological parameters increases the error on $f_{\rm NL}$ by 10 to 30% depending on the survey. Thus the $f_{\rm NL}$ constraint is remarkable robust to cosmological model uncertainties. On the other hand, if $N_\nu^{\rm rel}$ is simultaneously constrained from the data, the $f_{\rm NL}$ error increases by $\sim 80%$. Finally, future surveys which provide a large sample of galaxies or galaxy clusters over a volume comparable to the Hubble volume can measure primordial non-Gaussianity of the local form with a marginalized 1--$\sigma$ error of the order $\Delta f_{\rm NL} \sim 2-5$, after combination with CMB priors for the remaining cosmological parameters. These results are competitive with CMB bispectrum constraints achievable with an ideal CMB experiment.