Towards physically more comprehensive AGN modelling in cosmological simulations: A MACER-based modification of IllustrisTNG

TL;DR

This paper enhances cosmological galaxy simulations by integrating detailed AGN physics from the MACER model into the IllustrisTNG framework, improving the realism of black hole and galaxy evolution predictions.

Contribution

It introduces a MACER-based modification to the AGN feedback model in IllustrisTNG, capturing small-scale physics more accurately.

Findings

Higher star formation and black hole accretion rates in ellipticals with MACER-based feedback.

Better agreement with observed gas density profiles in simulations.

Improved reproduction of low-mass black holes in low-mass galaxies.

Abstract

Active galactic nuclei (AGN) feedback plays a significant role in many aspects of galaxy formation and evolution and has become a key ingredient in cosmological simulations. However, the subgrid models of AGN feedback in cosmological simulations such as IllustrisTNG (hereafter TNG) often overlook recent progress in the small-scale modelling of black hole (BH) accretion and AGN physics. In this study, we improve on this by incorporating central aspects of the MACER model, a framework that treats AGN physics in greater detail, into the TNG feedback implementation. Specifically, we adopt MACER-prescriptions for feedback output for high and low accretion rates in a new model while the estimation of the accretion rate remains unchanged. We test this updated scenario both for idealized elliptical galaxies and for a cosmological box. Compared to the original TNG model, the MACER-based simulation leads to a higher star formation rate (SFR) and BH accretion rate in ellipticals, yielding a gas density profile in better agreement with observations. In the cosmological simulations, the time evolution of the SFR density, galaxy stellar mass function at $z=0$, and $M_{\star}-M_{\rm BH}$ relation at $M_{\star}>10^{10.5}\,{\rm M_{\odot}}$ are similar in both models. The MACER model better reproduces low-mass BHs in low-mass galaxies, and yields milder quenching in massive galaxies, although this is accompanied by the absence of a pronounced colour bimodality. Still, the similarity of the outcomes underlines the self-regulated nature of BH feedback: for different feedback energetics, the accretion rate tends to adjust such that a similar total AGN feedback energy is released.