Galaxy Clustering in 3D and Modified Gravity Theories

Abstract

We study Modified Gravity (MG) theories by modelling the redshifted matter power spectrum in a spherical Fourier-Bessel (sFB) basis. We use a fully non-linear description of the real-space matter power-spectrum and include the lowest-order redshift-space correction (Kaiser effect), taking into account some additional non-linear contributions. Ignoring relativistic corrections, which are not expected to play an important role for a shallow survey, we analyse two different modified gravity scenarios, namely the generalised Dilaton scalar-tensor theories and the f(R) models in the large curvature regime. We compute the 3D power spectrum Cs(k1,k2) for various such MG theories with and without redshift space distortions, assuming precise knowledge of background cosmological parameters. Using an all-sky spectroscopic survey with Gaussian selection function (r) (-r2 / r20), r0 = 150 \, h-1 \, Mpc, and number density of galaxies N =10-4\;Mpc-3, we use a 2 analysis, and find that the lower-order ( ≤ 25) multipoles of Cs(k,k') (with radial modes restricted to k < 0.2 \, h \,Mpc-1) can constraint the parameter fR0 at a level of 2× 10-5 (3× 10-5) with 3 σ confidence for n=1(2). Combining constraints from higher > 25 modes can further reduce the error bars and thus in principle make cosmological gravity constraints competitive with solar system tests. However this will require an accurate modelling of non-linear redshift space distortions. Using a tomographic β(a)-m(a) parameterization we also derive constraints on specific parameters describing the Dilaton models of modified gravity.