Running Late: Testing Delayed Supermassive Black Hole Growth Models Against the Quasar Luminosity Function

TL;DR

This study tests models of supermassive black hole growth against quasar luminosity data, finding that a two-phase growth model with delayed early growth and subsequent accretion better explains observations than a simple linear relation.

Contribution

It introduces a semi-analytic two-phase SMBH growth model and demonstrates its superior fit to quasar luminosity functions compared to linear models.

Findings

Two-phase model fits the quasar luminosity function better.

Transition mass in the model aligns with simulation predictions.

Results support delayed SMBH growth in low-mass galaxies.

Abstract

Observations of massive galaxies at low redshift have revealed approximately linear scaling relations between the mass of a supermassive black hole (SMBH) and properties of its host galaxy. How these scaling relations evolve with redshift and whether they extend to lower-mass galaxies however remain open questions. Recent galaxy formation simulations predict a delayed, or "two-phase", growth of SMBHs: slow, highly intermittent BH growth due to repeated gas ejection by stellar feedback in low-mass galaxies, followed by more sustained gas accretion that eventually brings BHs onto the local scaling relations. The predicted two-phase growth implies a steep increase, or "kink", in BH-galaxy scaling relations at a stellar mass $M_{*}\sim5\times10^{10} M_{\odot}$. We develop a parametric, semi-analytic model to compare different SMBH growth models against observations of the quasar luminosity function (QLF) at $z\sim0.5-4$. We compare models in which the relation between SMBH mass and galaxy mass is purely linear versus two-phase models. The models are anchored to the observed galaxy stellar mass function, and the BH mass functions at different redshifts are consistently connected by the accretion rates contributing to the QLF. The best fits suggest that two-phase evolution is significantly preferred by the QLF data over a purely linear scaling relation. Moreover, when the model parameters are left free, the two-phase model fits imply a transition mass consistent with that predicted by simulations. Our analysis motivates further observational tests, including measurements of BH masses and AGN activity at the low-mass end, which could more directly test two-phase SMBH growth.