Bridging scales: Modeling suppressed Bondi accretion on black holes and its impact on galaxy growth

TL;DR

This study integrates magnetic suppression of Bondi accretion, demonstrated by GRMHD simulations, into a semi-analytic galaxy evolution model, revealing its significant impact on black hole and galaxy growth across cosmic time.

Contribution

It introduces a novel implementation of magnetic suppression effects from GRMHD simulations into a cosmological galaxy formation model, linking small-scale physics with large-scale galaxy evolution.

Findings

Magnetic suppression reduces SMBH accretion rates significantly.

Model reproduces observed low-redshift galaxy and black hole mass functions.

Supports rapid early black hole growth consistent with JWST observations.

Abstract

The accretion and feedback processes governing supermassive black hole (SMBH) growth span an enormous range of spatial scales, from the Event Horizon to the circumgalactic medium. Recent general relativistic magnetohydrodynamic (GRMHD) simulations demonstrate that strong magnetic fields can substantially suppress Bondi accretion by creating magnetically arrested disk (MAD) states, reducing inflow rates by up to two orders of magnitude relative to classical Bondi predictions. We incorporate this magnetic suppression prescription from Cho et al. (2023, 2024) into the Dark Sage semi-analytic model (SAM), which tracks SMBH and galaxy co-evolution within hierarchical merger trees derived from the IllustrisTNG cosmological simulation. Implementing the suppression across different Eddington-ratio regimes, we explore its impact on black hole mass functions (BHMFs), stellar mass functions (SMFs), and AGN luminosity functions. Restricting suppression to sub-Eddington accretors ($f_{\rm Edd} < 3 \times 10^{-3}$) and rescaling AGN feedback efficiencies gives simultaneous agreement with observed $z = 0$ SMFs and BHMFs, as illustrated by Case D in this work. At $z > 6$, super-Eddington growth episodes dominate in the SAM, reproducing JWST-inferred luminous AGN number densities. Our results highlight the critical sensitivity of galaxy assembly to the coupling between small-scale accretion physics and large-scale feedback regulation. Magnetic suppression of hot gas accretion can reconcile low-redshift constraints while preserving the rapid black hole growth required at early cosmic epochs, thereby providing a physically motivated bridge between horizon-scale GRMHD simulations and cosmological galaxy-formation models.