Evident black hole-bulge coevolution in the distant universe

Abstract

Observations in the local universe show a tight correlation between the masses of supermassive black holes (SMBHs; M BH) and host-galaxy bulges (M bulge), suggesting a strong connection between SMBH and bulge growth. However, direct evidence for such a connection in the distant universe remains elusive. We have studied sample-averaged SMBH accretion rate ( BHAR) for bulge-dominated galaxies at z=0.5-3. While previous observations found BHAR is strongly related to host-galaxy stellar mass (M) for the overall galaxy population, our analyses show that, for the bulge-dominated population, BHAR is mainly related to SFR rather than M. This BHAR-SFR relation is highly significant, e.g. 9.0σ (Pearson statistic) at z=0.5-1.5. Such a BHAR-SFR connection does not exist among our comparison sample of galaxies that are not bulge-dominated, for which M appears to be the main determinant of SMBH accretion. This difference between the bulge-dominated and comparison samples indicates that SMBHs only coevolve with bulges rather than the entire galaxies, explaining the tightness of the local M BH-M bulge correlation. Our best-fit BHAR-SFR relation for the bulge-dominated sample is BHAR = - (2.480.05) (solar units). The best-fit BHAR/SFR ratio (10-2.48) for bulge-dominated galaxies is similar to the observed M BH/M bulge values in the local universe. Our results reveal that SMBH and bulge growth are in lockstep, and thus non-causal scenarios of merger averaging are unlikely the origin of the M BH-M bulge correlation. This lockstep growth also predicts that the M BH-M bulge relation should not have strong redshift dependence.