An Eddington ratio-driven origin for the L X- M* relation in quiescent and star forming active galaxies

Abstract

A mild correlation exists in active galaxies between the mean black hole accretion, as traced by the mean X-ray luminosity < L X>, and the host galaxy stellar mass M*, characterised by a normalisation steadily decreasing with cosmic time and lower in more quiescent galaxies. We create comprehensive semi-empirical mock catalogues of active black holes to pin down which parameters control the shape and evolution of the < L X>- M* relation of X-ray detected active galaxies. We find that the normalisation of the < L X>- M* relation is largely independent of the fraction of active galaxies (the duty cycle), but strongly dependent on the mean Eddington ratio, when adopting a constant underlying M BH- M* relation as suggested by observational studies. The data point to a decreasing mean Eddington ratio with cosmic time and with galaxy stellar mass at fixed redshift. Our data can be reproduced by black holes and galaxies evolving on similar M BH- M* relations but progressively decreasing their average Eddington ratios, mean X-ray luminosities, and specific star formation rates, when moving from the starburst to the quiescent phase. Models consistent with the observed < L X>- M* relation and independent measurements of the mean Eddington ratios, are characterised by M BH- M* relations lower than those derived from dynamically measured local black holes. Our results point to the < L X>- M* relation as a powerful diagnostic to: 1) probe black hole-galaxy scaling relations and the level of accretion onto black holes; 2) efficiently break the degeneracies between duty cycles and accretion rates in cosmological models of black holes.