Redshift-Space Distortions and the Real-Space Clustering of Different Galaxy Types
Abstract
We study the distortions induced by peculiar velocities on the redshift-space correlation function of galaxies of different morphological types in the Pisces-Perseus redshift survey. Redshift-space distortions affect early- and late-type galaxies in different ways. In particular, at small separations, the dominant effect comes from virialized cluster cores, where ellipticals are the dominant population. The net result is that a meaningful comparison of the clustering strength of different morphological types can be performed only in real space, i.e., after projecting out the redshift distortions on the two-point correlation function xi(rp,pi). A power-law fit to the projected function wp(rp) on scales smaller than 10/h Mpc gives ro = 8.35-0.76+0.75 /h Mpc, γ = 2.05-0.08+0.10 for the early-type population, and ro = 5.55-0.45+0.40 /h Mpc, γ = 1.73-0.08+0.07 for spirals and irregulars. These values are derived for a sample luminosity brighter than MZw = -19.5. We detect a 25% increase of ro with luminosity for all types combined, from MZw = -19 to -20. In the framework of a simple stable-clustering model for the mean streaming of pairs, we estimate sigma12(1), the one-dimensional pairwise velocity dispersion between 0 and 1 /h Mpc, to be 865+250-165 km/s for early-type galaxies and 345+95-65 km/s for late types. This latter value should be a fair estimate of the pairwise dispersion for ``field'' galaxies; it is stable with respect to the presence or absence of clusters in the sample, and is consistent with the values found for non-cluster galaxies and IRAS galaxies at similar separations.
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