The Effect of Large-Scale Structure on the SDSS Galaxy Three-Point Correlation Function

Abstract

We present measurements of the normalised redshift-space three-point correlation function (Qz) of galaxies from the Sloan Digital Sky Survey (SDSS) main galaxy sample. We have applied our "npt" algorithm to both a volume-limited (36738 galaxies) and magnitude-limited sample (134741 galaxies) of SDSS galaxies, and find consistent results between the two samples, thus confirming the weak luminosity dependence of Qz recently seen by other authors. We compare our results to other Qz measurements in the literature and find it to be consistent within the full jack-knife error estimates. However, we find these errors are significantly increased by the presence of the ``Sloan Great Wall'' (at z ~ 0.08) within these two SDSS datasets, which changes the 3-point correlation function (3PCF) by 70% on large scales (s>=10h-1 Mpc). If we exclude this supercluster, our observed Qz is in better agreement with that obtained from the 2dFGRS by other authors, thus demonstrating the sensitivity of these higher-order correlation functions to large-scale structures in the Universe. This analysis highlights that the SDSS datasets used here are not ``fair samples'' of the Universe for the estimation of higher-order clustering statistics and larger volumes are required. We study the shape-dependence of Qz(s,q,theta) as one expects this measurement to depend on scale if the large scale structure in the Universe has grown via gravitational instability from Gaussian initial conditions. On small scales (s <= 6h-1 Mpc), we see some evidence for shape-dependence in Qz, but at present our measurements are consistent with a constant within the errors (Qz ~ 0.75 +/- 0.05). On scales >10h-1 Mpc, we see considerable shape-dependence in Qz.

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