Timescales of Quasar Accretion Discs from Low to High Black Hole Masses and a Turnover at the High Mass End
Abstract
Characteristic time scales in the stochastic UV-optical variability of quasars may depend on the mass of their black holes, M BH, as much as physical timescales in their accretion discs do. We calculate emission-weighted mean radii, R mean, and orbital timescales, t mean, of standard thin disc models for emission wavelengths λ from 1000 to 10000 AA, M BH from 106 to 1011 solar masses, and Eddington ratios from 0.01 to 1. At low M BH, we find the textbook behaviour of t mean M BH-1/2 alongside R mean ≈ const, but toward higher masses the growing event horizon imposes R mean M BH and thus a turnover into t mean M BH. For quasars of L bol=47, the turnover mass, where t mean starts rising is M BH≈ 9.5, which means that the turnover in t mean is well within the range of high-luminosity quasar samples, whose variability time scales might thus show little mass dependence. We fit smoothly broken power laws to the results and provide analytic convenience functions for R mean(λ,M BH,L3000) and t mean(λ,M BH,L3000).
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