Assembly bias in the local PNG halo bias and its implication for f NL constraints

Abstract

We use N-body simulations to study halo assembly bias (i.e., the dependence of halo clustering on properties beyond total mass) in the density and primordial non-Gaussianity (PNG) linear bias parameters b1 and bφ, respectively. We consider concentration, spin and sphericity as secondary halo properties, for which we find a clear detection of assembly bias for b1 and bφ. At fixed total mass, halo spin and sphericity impact b1 and bφ in a similar manner, roughly preserving the shape of the linear bφ(b1) relation satisfied by the global halo population. Halo concentration, however, drives b1 and bφ in opposite directions. This induces significant changes to the bφ(b1) relation, with higher concentration halos having higher amplitude of bφ(b1). For z=0.5 and b1 ≈ 2 in particular, the population comprising either all halos, those with the 33\% lowest or those with the 33\% highest concentrations have a PNG bias of bφ ≈ 3, bφ ≈ -1 and bφ ≈ 9, respectively. Varying the halo concentration can make bφ very small and even change its sign. These results have important ramifications for galaxy clustering constraints of the local PNG parameter f NL that assume fixed forms for the bφ(b1) relation. We illustrate the significant impact of halo assembly bias in actual data using the BOSS DR12 galaxy power spectrum: assuming that BOSS galaxies are representative of all halos, the 33\% lowest or the 33\% highest concentration halos yields σf NL = 44, 165, 19, respectively. Our results suggest taking host halo concentration into account in galaxy selection strategies to maximize the signal-to-noise on f NL. They also motivate more simulation-based efforts to study the bφ(b1) relation of halos and galaxies.