Correlation function of quasars in real and redshift space from the Sloan Digital Sky Survey Data Release 7

Abstract

We analyze the quasar two-point correlation function (2pCF) within the redshift interval 0.8<z<2.2 using a sample of 52303 quasars selected from the recent 7th Data Release of the Sloan Digital Sky Survey. Our approach to 2pCF uses a concept of locally Lorentz (Fermi) frame for determination of the distance between objects and permutation method of the random catalogue generation. Assuming the spatially flat cosmological model with given =0.726, we found that the real-space 2pCF is fitted well with the power-low model within the distance range 1<σ<35 h-1 Mpc with the correlation length r0=5.850.33 h-1 Mpc and the slope γ=1.870.07. The redshift-space 2pCF is approximated with s0=6.430.63 h-1 Mpc and γ=1.210.24 for 1<s<10 h-1 Mpc, and s0=7.370.81 h-1 Mpc and γ=1.900.24 for 10<s<35 h-1 Mpc. For distances s>10\,h-1 Mpc the parameter describing the large-scale infall to density inhomogeneities is β=0.630.10 with the linear bias b=1.440.22 that marginally (within 2σ) agrees with the linear theory of cosmological perturbations. We discuss possibilities to obtain a statistical estimate of the random component of quasars velocities (different from the large-scale infall). We note rather slight dependence of quasars velocity dispersion upon the 2pCF parameters in the region r<2 Mpc.