Physical properties of AGN host galaxies as a probe of SMBH feeding mechanisms

TL;DR

This study uses a semi-analytic galaxy formation model to compare two AGN triggering mechanisms—disk instabilities and galaxy interactions—and their effects on host galaxy properties, providing insights into SMBH feeding processes.

Contribution

It introduces a comparative analysis of disk instability and interaction-driven AGN fueling modes using advanced modeling, highlighting observable differences in host galaxy characteristics.

Findings

Both modes explain AGN host stellar mass functions for M* < 10^{11} M_sun.

Color-magnitude diagrams can distinguish between the two modes at z<1.5.

Disk instabilities fail to trigger AGN in passive galaxies and do not match observed AGN fractions in groups and clusters.

Abstract

Using an advanced semi analytic model (SAM) for galaxy formation, we have investigated the statistical effects of assuming two different mechanisms for triggering AGN activity on the properties of AGN host galaxies. We have considered a first accretion mode where AGN activity is triggered by disk instabilities (DI) in isolated galaxies, and a second feeding mode where such an activity is triggered by galaxy mergers and fly-by events (interactions, IT). We obtained the following results:i) for hosts with $M_* \lesssim 10^{11} M_{\bigodot}$, both DI and IT modes are able to account for the observed AGN hosts stellar mass function; for more massive hosts, the DI scenario predicts a lower space density than the IT model, lying below the observational estimates for z>0.8.ii) The analysis of the color-magnitude diagram (CMD) of AGN hosts for redshift z < 1.5 can provide a good observational test to effectively discriminate between the DI and IT mode, since DIs are expected to yield AGN host galaxy colors skewed towards bluer colors, while in the IT scenario the majority of hosts are expected to reside in the red sequence.iii) While both IT and DI scenarios can account for AGN triggered in main sequence or starburst galaxies, DIs fail in triggering AGN activity in passive galaxies.iv) The two modes are characterized by a different duration of the AGN phase, with DIs lasting even on time scales $\sim $ Gyr, much longer with respect to the IT scenario.v) The scatter of the $SFR-L_{bol}$ relation could represent another crucial diagnostics to discriminate between the two triggering modes, since the DI scenario predicts an appreciably lower scatter of the relation than the IT scenario. vi) Disk instabilities are not able to account for the observed fraction of AGN in groups for z < 1 and clusters for z < 0.7, while the IT scenario provides a good match to observational data.