Nonlinear stochastic growth rates and redshift space distortions

Abstract

The linear growth rate is commonly defined through a simple deterministic relation between the velocity divergence and the matter overdensity in the linear regime. We introduce a formalism that extends this to a nonlinear, stochastic relation between θ = ∇ · v( x,t)/aH and δ. This provides a new phenomenological approach that examines the conditional mean < θ|δ>, together with the fluctuations of θ around this mean. We measure these stochastic components using N-body simulations and find they are non-negative and increase with decreasing scale from 10% at k<0.2 h Mpc-1 to 25% at k0.45hMpc-1 at z = 0. Both the stochastic relation and nonlinearity are more pronounced for halos, M 5 × 1012M h-1, compared to the dark matter at z=0 and 1. Nonlinear growth effects manifest themselves as a rotation of the mean < θ|δ> away from the linear theory prediction -f LTδ, where f LT is the linear growth rate. This rotation increases with wavenumber, k, and we show that it can be well-described by second order Lagrangian perturbation theory (2LPT) for k < 0.1 hMpc-1. The stochasticity in the θ -- δ relation is not so simply described by 2LPT, and we discuss its impact on measurements of f LT from two point statistics in redshift space. Given that the relationship between δ and θ is stochastic and nonlinear, this will have implications for the interpretation and precision of f LT extracted using models which assume a linear, deterministic expression.