Redshift-space equal-time angular-averaged consistency relations of the gravitational dynamics

Abstract

We present the redshift-space generalization of the equal-time angular-averaged consistency relations between (+n)- and n-point polyspectra of the cosmological matter density field. Focusing on the case of =1 large-scale mode and n small-scale modes, we use an approximate symmetry of the gravitational dynamics to derive explicit expressions that hold beyond the perturbative regime, including both the large-scale Kaiser effect and the small-scale fingers-of-god effects. We explicitly check these relations, both perturbatively, for the lowest-order version that applies to the bispectrum, and nonperturbatively, for all orders but for the one-dimensional dynamics. Using a large ensemble of N-body simulations, we find that our squeezed bispectrum relation is valid to better than 20\% up to 1hMpc-1, for both the monopole and quadrupole at z=0.35, in a cosmology. Additional simulations done for the Einstein-de Sitter background suggest that these discrepancies mainly come from the breakdown of the approximate symmetry of the gravitational dynamics. For practical applications, we introduce a simple ansatz to estimate the new derivative terms in the relation using only observables. Although the relation holds worse after using this ansatz, we can still recover it within 20\% up to 1hMpc-1, at z=0.35 for the monopole. On larger scales, k = 0.2 hMpc-1, it still holds within the statistical accuracy of idealized simulations of volume 8h-3Gpc3 without shot-noise error.