Bounds on Neutrino Mass in Viscous Cosmology

Abstract

Effective field theory of dark matter fluid on large scales predicts the presence of viscosity of the order of 10-6 H0 MP2. It has been shown that this magnitude of viscosities can resolve the discordance between large scale structure observations and Planck CMB data in the σ8-m0 and H0-m0 parameters space. Massive neutrinos suppresses the matter power spectrum on the small length scales similar to the viscosities. We show that by including the effective viscosity, which arises from summing over non linear perturbations at small length scales, severely constrains the cosmological bound on neutrino masses. Under a joint analysis of Planck CMB and different large scale observation data, we find that upper bound on the sum of the neutrino masses at 2-σ level, decreases from Σ m 0.396\,eV (normal hierarchy) and Σ m 0.378 \,eV (inverted hierarchy) to Σ m 0.267\,eV (normal hierarchy) and Σ m 0.146\,eV (inverted hierarchy) when the effective viscosities are included.