The first measurement of the quasar lifetime distribution

Abstract

Understanding the growth of the supermassive black holes powering luminous quasars, their co-evolution with host galaxies, and impact on the surrounding intergalactic medium depends sensitively on the duration of quasar accretion episodes. Unfortunately, this time-scale, known as the quasar lifetime, t Q, is still uncertain by orders of magnitude (t Q 0.01~ Myr-1~ Gyr). However, the extent of the He II Lyα proximity zones in the absorption spectra of z qso3-4 quasars constitutes a unique probe, providing sensitivity to lifetimes up to 30 Myr. Our recent analysis of 22 archival He II proximity zone spectra reveals a surprisingly broad range of emission timescales, indicating that some quasars turned on 1 Myr ago, whereas others have been shining for 30 Myr. Determining the underlying quasar lifetime distribution (QLD) from proximity zone measurements is a challenging task owing to: 1) the limited sensitivity of individual measurements; 2) random sampling of the quasar light curves; 3) density fluctuations in the quasar environment; and 4) the inhomogeneous ionization state of He II in a reionizing IGM. We combine a semi-numerical He II reionization model, hydrodynamical simulations post-processed with ionizing radiative transfer, and a novel statistical framework to infer the QLD from an ensemble of proximity zone measurements. Assuming a log-normal QLD, we infer a mean log10(t Q/ Myr)=0.22+0.22-0.25 and standard deviation σ log10t Q=0.80+0.37-0.27. Our results allow us to estimate the probability of detecting young quasars with t Q≤0.1 Myr from their proximity zone sizes yielding p(≤ 0.1~ Myr)=0.19+0.11-0.09, which is broadly consistent with recent determination at z 6.