Squeezing f NL out of the matter bispectrum with consistency relations

Abstract

We show how consistency relations can be used to robustly extract the amplitude of local primordial non-Gaussianity (f NL) from the squeezed limit of the matter bispectrum, well into the non-linear regime. First, we derive a non-perturbative relation between primordial non-Gaussianity and the leading term in the squeezed bispectrum, revising some results present in the literature. This relation is then used to successfully measure f NL from N-body simulations. We discuss the dependence of our results on different scale cuts and redshifts. Specifically, the analysis is strongly dependent on the choice of the smallest soft momentum, q min, which is the most sensitive to primordial bispectrum contributions, but is largely independent of the choice of the largest hard momentum, k max, due to the non-Gaussian nature of the covariance. We also show how the constraints on f NL improve at higher redshift, due to a reduced off-diagonal covariance. In particular, for a simulation with f NL = 100 and a volume of (2.4 Gpc/h)3, we measure f NL = 98 12 at redshift z=0 and f NL = 97 8 at z=0.97. Finally, we compare our results with a Fisher forecast, showing that the current version of the analysis is satisfactorily close to the Fisher error. We regard this as a first step towards the realistic application of consistency relations to constrain primordial non-Gaussianity using observations.