We present a clustering analysis of QSOs over the redshift range z=0.3-2.9. We use a sample of 10558 QSOs taken from the preliminary catalogue of the 2dF QSO Redshift Survey (2QZ). The two-point redshift-space correlation function of QSOs is shown to follow a power law on scales s~1-35h-1Mpc. Fitting a power law to QSO clustering averaged over the redshift interval 0.3<z<2.9 we find s_0=3.99+0.28-0.34h-1Mpc and gamma=1.58+0.10-0.09 for an Einstein-de Sitter cosmology (EdS). With Omega_0=0.3 and lambda_0=0.7 the power law extends to s~60h-1Mpc with a best fit of s_0=5.69+0.42-0.50h-1Mpc and gamma=1.56+0.10-0.09. These values, measured at a mean redshift of z=1.49, are comparable to the clustering of local optically selected galaxies. We measure the evolution of QSO clustering as a function of redshift. For an EdS cosmology there is no evolution in comoving coordinates over the redshift range of the 2QZ. For Omega_0=0.3 and lambda_0=0.7 QSO clustering shows a marginal increase at high redshift. Although the clustering of QSOs is measured on large scales where linear theory should apply, the evolution of QSO clustering does not follow the linear theory predictions for growth via gravitational instability (rejected at the >99 per cent confidence level). A redshift dependent bias is required to reconcile QSO clustering observations with theory. A simple biasing model, in which QSOs have cosmologically long lifetimes (or alternatively form in peaks above a constant threshold in the density field) is acceptable in an EdS cosmology, but is only marginally acceptable if Omega_0=0.3 and lambda_0=0.7. Biasing models which assume QSOs form over a range in redshift, based on the Press-Schechter formalism are approximately consistent with QSO clustering evolution (abridged).
تحميل البحث