Constraining neutrino properties with a Euclid-like galaxy cluster survey

Abstract

We perform a forecast analysis on how well a Euclid-like photometric galaxy cluster survey will constrain the total neutrino mass and effective number of neutrino species. We base our analysis on the Monte Carlo Markov Chains technique by combining information from cluster number counts and cluster power spectrum. We find that combining cluster data with CMB measurements from Planck improves by more than an order of magnitude the constraint on neutrino masses compared to each probe used independently. For the LCDM+mnu model the 2 sigma upper limit on total neutrino mass shifts from Mnu < 0.35 eV using cluster data alone to Mnu < 0.031 eV when combined with CMB data. When a non-standard model with Neff number of neutrino species is considered, we estimate Neff<3.14 (95% CL), while the bounds on neutrino mass are relaxed to Mnu < 0.040 eV. This accuracy would be sufficient for a 2 sigma detection of neutrino mass even in the minimal normal hierarchy scenario. We also consider scenarios with a constant dark energy equation of state and a non-vanishing curvature. When these models are considered the error on Mnu is only slightly affected, while there is a larger impact of the order of ~ 15 % and ~ 20% respectively on the 2 sigma error bar of Neff with respect to the standard case. We also treat the LCDM+mnu+Neff case with free nuisance parameters, which parameterize the uncertainties on the cluster mass determination. In this case, the upper bounds on Mnu are relaxed by a factor larger than two, Mnu < 0.083 eV (95% CL), hence compromising the possibility of detecting the total neutrino mass with good significance. We thus confirm the potential that a large optical/near-IR cluster survey, like that to be carried out by Euclid, could have in constraining neutrino properties [abridged].