Two-loop power spectrum with full time- and scale-dependence and EFT corrections: impact of massive neutrinos and going beyond EdS
Abstract
We compute the density and velocity power spectra at next-to-next-to-leading order taking into account the effect of time- and scale-dependent growth of massive neutrino perturbations as well as the departure from Einstein--de-Sitter (EdS) dynamics at late times non-linearly. We determine the impact of these effects by comparing to the commonly adopted approximate treatment where they are not included. For the bare cold dark matter (CDM)+baryon spectrum, we find percent deviations for k 0.17h~Mpc-1, mainly due to the departure from EdS. For the velocity and cross power spectrum the main difference arises due to time- and scale-dependence in presence of massive neutrinos yielding percent deviation above k 0.08, 0.13, 0.16h~Mpc-1 for Σ m = 0.4, 0.2, 0.1~eV, respectively. We use an effective field theory (EFT) framework at two-loop valid for wavenumbers k kFS, where kFS is the neutrino free-streaming scale. Comparing to Quijote N-body simulations, we find that for the CDM+baryon density power spectrum the effect of neutrino perturbations and exact time-dependent dynamics at late times can be accounted for by a shift in the one-loop EFT counterterm, γ1 - 0.2~Mpc2/h2. We find percent agreement between the perturbative and N-body results up to k 0.12h~Mpc-1 and k 0.16h~Mpc-1 at one- and two-loop order, respectively, for all considered neutrino masses Σ m ≤ 0.4~eV.
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