Testing growth rate dependence in cosmological perturbation theory using scale-free models

Abstract

We generalize previously derived analytic results for the one-loop power spectrum (PS) in scale-free models (with linear PS P(k) kn) to a broader class of such models in which part of the matterlike component driving the Einstein de Sitter expansion does not cluster. These models can be conveniently parametrized by α, the constant logarithmic linear growth rate of fluctuations (with α=1 in the usual case). For -3< n<-1, where the one-loop PS is both infrared and ultraviolet convergent and thus explicitly self-similar, it is characterized conveniently by a single numerical coefficient c(n, α). We compare the analytical predictions for c(n=-2, α) with results from a suite of N-body simulations with α ∈ [0.25, 1] performed with an appropriately modified version of the GADGET code. Although the simulations are of small (2563) boxes, the constraint of self-similarity allows the identification of the converged PS at a level of accuracy sufficient to test the analytical predictions for the α dependence of the evolved PS. Good agreement for the predicted dependence on α of the PS is found. To treat the UV sensitivity of results which grows as one approaches n =-1, we derive exact results incorporating a regularization kc and obtain expressions for c(n, α, kc/k). Assuming that this regularization is compatible with self-similarity allows us to infer a predicted functional form of the PS equivalent to that derived in effective field theory (EFT). The coefficient of the leading EFT correction at one loop has a strong dependence on α, with a change in sign at α ≈ 0.16, providing a potentially stringent test of EFT.