The coevolution of supermassive black holes and galaxies in luminous AGN over a wide range of redshift

TL;DR

This study investigates the co-evolution of supermassive black holes and their host galaxies across a wide redshift range, finding a stable black hole to galaxy mass ratio and evidence that black hole growth precedes stellar mass assembly.

Contribution

It provides new observational evidence on the non-evolving M$_{BH}$-M$_*$ relation up to z=2 using a large sample of luminous AGN, highlighting black hole growth as an early process.

Findings

M$_{BH}$ and M$_*$ are correlated with r=0.47±0.21.

The mean M$_{BH}$/M$_*$ ratio remains constant up to z=2.

75% of AGN are in a black hole growth dominant phase.

Abstract

It is well known that supermassive black holes (SMBHs) and their host galaxies co-evolve. A manifestation of this co-evolution is the correlation that has been found between the SMBH mass, M$_{BH}$, and the galaxy bulge or stellar mass, M$_*$. The cosmic evolution of this relation, though, is still a matter of debate. In this work, we examine the M$_{BH}-$M$_*$ relation, using 687 X-ray luminous (median $\rm log\,[L_{X,2-10keV}(ergs^{-1})]=44.3$), broad line AGN, at $\rm 0.2<z<4.0$ (median $\rm z\approx 1.4$) that lie in the XMM-{\it{XXL}} field. Their M$_{BH}$ and M$_*$ range from $\rm 7.5<log\,[M_{BH}\,(M_\odot)]<9.5$ and $\rm 10<log\,[M_*(M_\odot)]<12$, respectively. Most of the AGN live in star-forming galaxies and their Eddington ratios range from 0.01 to 1, with a median value of 0.06. Our results show that M$_{BH}$ and M$_*$ are correlated ($\rm r=0.47\pm0.21$, averaged over different redshift intervals). Our analysis also shows that the mean ratio of the M$_{BH}$ and M$_*$ does not evolve with redshift, at least up to $\rm z=2$ and has a value of $\rm log($M$_{BH}/$M$_*)=-2.44$. The majority of the AGN ($75\%$) are in a SMBH mass growth dominant phase. In these systems, the M$_{BH}-$M$_*$ correlation is weaker and their M$_*$ tends to be lower (for the same M$_{BH}$) compared to systems that are in a galaxy mass growth phase. Our findings suggest that the growth of black hole mass occurs first, while the early stellar mass assembly may not be so efficient.