The halo mass of optically-luminous quasars at z=1-2 measured via gravitational deflection of the cosmic microwave background

Abstract

We measure the average deflection of cosmic microwave background photons by quasars at z =1.7. Our sample is selected from the Sloan Digital Sky Survey to cover the redshift range 0.9≤ z≤2.2 with absolute i-band magnitudes of Mi≤-24 (K-corrected to z=2). A stack of nearly 200,000 targets reveals an 8σ detection of Planck's estimate of the lensing convergence towards the quasars. We fit the signal with a model comprising a Navarro-Frenk-White density profile and a 2-halo term accounting for correlated large scale structure, which dominates the observed signal. The best-fitting model is described by an average halo mass 10(M h/h-1M)=12.60.2 and linear bias b=2.70.3 at z=1.7, in excellent agreement with clustering studies. We also report of a hint, at a 90% confidence level, of a correlation between the convergence amplitude and luminosity, indicating that quasars brighter than Mi -26 reside in halos of typical mass M h≈ 1013\,h-1M, scaling roughly as M h L opt3/4 at Mi-24, in good agreement with physically-motivated quasar demography models. Although we acknowledge this luminosity dependence is a marginal result, the observed M h-L opt relationship could be interpreted as a reflection of the cutoff in the distribution of black hole accretion rates towards high Eddington ratios: the weak trend of M h with L opt observed at low luminosity becomes stronger for the most powerful quasars, which tend to be accreting close to the Eddington limit.