The Effective Field Theory of Large-Scale Structure in the presence of Massive Neutrinos

Abstract

We develop a formalism to analytically describe the clustering of matter in the mildly non-linear regime in the presence of massive neutrinos. Neutrinos, whose free streaming wavenumber (k fs) is typically longer than the non-linear scale (k NL) are described by a Boltzmann equation coupled to the effective fluid-like equations that describe dark matter. We solve the equations expanding in the neutrino density fraction (f) and in k/ k NL, and add suitable counterterms to renormalize the theory. This allows us to describe the contribution of short distances to long-distance observables. Equivalently, we construct an effective Boltzmann equation where we add additional terms whose coefficients renormalize the contribution from short-distance physics. We argue that neutrinos with k fs k NL require an additional counterterm similar to the speed of sound (cs) for dark matter. We compute the one-loop total-matter power spectrum, and find that it is roughly equal to 16f times the dark matter one for k's larger that the typical k fs. It is about half of that for smaller k's. The leading contribution results from the back-reaction of the neutrinos on the dynamics of the dark matter. The counterterms contribute in a hierarchical way: the leading ones can either be computed in terms of cs, or can be accounted for by shifting cs by an amount proportional to f.