Cosmology in the era of Euclid and the Square Kilometre Array

Abstract

Theoretical uncertainties on non-linear scales are among the main obstacles to exploit the sensitivity of forthcoming galaxy and hydrogen surveys like Euclid or the Square Kilometre Array (SKA). Here, we devise a new method to model the theoretical error that goes beyond the usual cut-off on small scales. The advantage of this more efficient implementation of the non-linear uncertainties is tested through a Markov-Chain-Monte-Carlo (MCMC) forecast of the sensitivity of Euclid and SKA to the parameters of the standard model, including massive neutrinos with total mass M, and to 3 extended scenarios, including 1) additional relativistic degrees of freedom ( + M + Neff), 2) a deviation from the cosmological constant ( + M + w0), and 3) a time-varying dark energy equation of state parameter ( + M + (w0,wa )). We compare the sensitivity of 14 different combinations of cosmological probes and experimental configurations. For Euclid combined with Planck, assuming a plain cosmological constant, our method gives robust predictions for a high sensitivity to the primordial spectral index n s (σ(ns)=0.00085), the Hubble constant H0 (σ(H0)=0.141 \, km/s/Mpc), the total neutrino mass M (σ(M)=0.020 \, eV). Assuming dynamical dark energy we get σ(M)=0.030 \, eV for the mass and (σ(w0), σ(wa)) = (0.0214, 0.071) for the equation of state parameters. The predicted sensitivity to M is mostly stable against the extensions of the cosmological model considered here. Interestingly, a significant improvement of the constraints on the extended model parameters is also obtained when combining Euclid with a low redshift HI intensity mapping survey by SKA1, demonstrating the importance of the synergy of Euclid and SKA.