Testing the Completeness of the SDSS Colour Selection for Ultramassive, Slowly Spinning Black Holes

Abstract

We investigate the sensitivity of the colour-based quasar selection algorithm of the Sloan Digital Sky Survey to several key physical parameters of supermassive black holes (SMBHs), focusing on BH spin (a) at the high BH-mass regime (MBH ≥slant109\, M). We use a large grid of model spectral energy distribution, assuming geometrically-thin, optically-thick accretion discs, and spanning a wide range of five physical parameters: BH mass MBH, BH spin a, Eddington ratio L / LEdd , redshift z, and inclination angle inc. Based on the expected fluxes in the SDSS imaging ugriz bands, we find that 99.8\% of our models with MBH ≤slant 109.5\, M are selected as quasar candidates and thus would have been targeted for spectroscopic follow-up. However, in the extremely high-mass regime, ≥slant 1010 M, we identify a bias against slowly/retrograde spinning SMBHs. The fraction of SEDs that would have been selected as quasar candidates drops below 50\% for a <0 across 0.5<z<2. For particularly massive BHs, with MBH 3×1010\, M, this rate drops below 20\%, and can be yet lower for specific redshifts. We further find that the chances of identifying any hypothetical sources with MBH = 1011\, M by colour selection would be extremely low at the level of 3\%. Our findings, along with several recent theoretical arguments and empirical findings, demonstrate that the current understanding of the SMBH population at the high-MBH, and particularly the low- or retrograde-spinning regime, is highly incomplete.