Quasar Clustering from SDSS DR5: Dependences on Physical Properties

TL;DR

This study analyzes how quasar clustering varies with properties like luminosity, black hole mass, color, and radio loudness using SDSS DR5 data, revealing weak dependencies and stronger clustering for the most luminous, massive, and radio-loud quasars.

Contribution

It provides the first detailed analysis of quasar clustering dependence on multiple physical properties using a large SDSS DR5 sample, highlighting the role of halo mass and bias.

Findings

Weak dependence of clustering on luminosity and black hole mass.

Radio-loud quasars are more strongly clustered than radio-quiet ones.

Most luminous and massive quasars show increased clustering at ~2σ significance.

Abstract

Using a homogenous sample of 38,208 quasars with a sky coverage of $4000 {\rm deg^2}$ drawn from the SDSS Data Release Five quasar catalog, we study the dependence of quasar clustering on luminosity, virial black hole mass, quasar color, and radio loudness. At $z<2.5$, quasar clustering depends weakly on luminosity and virial black hole mass, with typical uncertainty levels $\sim 10%$ for the measured correlation lengths. These weak dependences are consistent with models in which substantial scatter between quasar luminosity, virial black hole mass and the host dark matter halo mass has diluted any clustering difference, where halo mass is assumed to be the relevant quantity that best correlates with clustering strength. However, the most luminous and most massive quasars are more strongly clustered (at the $\sim 2\sigma$ level) than the remainder of the sample, which we attribute to the rapid increase of the bias factor at the high-mass end of host halos. We do not observe a strong dependence of clustering strength on quasar colors within our sample. On the other hand, radio-loud quasars are more strongly clustered than are radio-quiet quasars matched in redshift and optical luminosity (or virial black hole mass), consistent with local observations of radio galaxies and radio-loud type 2 AGN. Thus radio-loud quasars reside in more massive and denser environments in the biased halo clustering picture. Using the Sheth et al.(2001) formula for the linear halo bias, the estimated host halo mass for radio-loud quasars is $\sim 10^{13} h^{-1}M_\odot$, compared to $\sim 2\times 10^{12} h^{-1}M_\odot$ for radio-quiet quasar hosts at $z\sim 1.5$.