Abstract
Redshift-space distortions (RSD) offer an attractive method to measure the growth of cosmic structure on large scales, and combining with the measurement of the cosmic expansion history, it can be used as cosmological tests of gravity. With the advent of future galaxy redshift surveys aiming at precisely measuring the RSD, an accurate modeling of RSD going beyond linear theory is a critical issue in order to detect or disprove small deviations from general relativity (GR). While several improved models of RSD have been recently proposed based on the perturbation theory (PT), the framework of these models heavily relies on GR. Here, we put forward a new PT prescription for RSD in general modified gravity models. As a specific application, we present theoretical predictions of the redshift-space power spectra in f(R) gravity model, and compare them with N-body simulations. Using the PT template that takes into account the effects of both modifications of gravity and RSD properly, we successfully recover the fiducial model parameter in N-body simulations in an unbiased way. On the other hand, we found it difficult to detect the scale dependence of the growth rate in a model-independent way based on GR templates.
Highlights
We studied how well we can clarify the nature of gravity at large scales with redshift-space distortions, especially focusing on the quasilinear regime of the gravitational evolution
Extending our previous works on the improved model of Redshift-space distortions (RSDs) proposed by Ref. [22], we applied the standard PT framework from
Ref. [52], which has been formulated to deal with a wide class of modified gravity models, to the computation of the redshift-space power spectrum
Summary
Redshift-space distortions (RSDs) of galaxy clustering, which appear as systematic effects in determining the redshift of each galaxy via spectroscopic measurements and manifestly break statistical isotropy [1,2], are recognized as a sensitive probe of the growth of structure. Based on the perturbation theory of large-scale structure, several improved models of RSD have been proposed [22,23,24,25,26,27,28,29,30] These models properly account for the non-Gaussian nature of RSD, and are tested against N-body simulations, successfully describing a redshift-space power spectrum and/or correlation function at a weakly nonlinear regime. Applying these models to real observations, constraints on the growth of structure have been obtained (e.g., [31,32]).
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