The FABLE simulations: A feedback model for galaxies, groups and clusters

TL;DR

The FABLE simulations are advanced cosmological hydrodynamical models that successfully reproduce many observed properties of galaxies, groups, and clusters, providing insights into feedback processes and scaling relations.

Contribution

This work introduces the FABLE simulation suite with updated feedback models, achieving improved agreement with observed galaxy and cluster properties across multiple scales.

Findings

Good match with observed scaling relations for groups and clusters.

Discrepancies suggest possible X-ray mass bias in observations.

Inner entropy profiles indicate need for better AGN feedback modeling.

Abstract

We present the Feedback Acting on Baryons in Large-scale Environments (FABLE) suite of cosmological hydrodynamical simulations of galaxies, groups and clusters. The simulations use the AREPO moving-mesh code with a set of physical models for galaxy formation based on the successful Illustris simulation, but with updated AGN and supernovae feedback models. This allows us to simultaneously reproduce the observed redshift evolution of the galaxy stellar mass function together with the stellar and gas mass fractions of local groups and clusters across a wide range of halo masses. Focusing on the properties of groups and clusters, we find very good agreement with a range of observed scaling relations, including the X-ray luminosity--total mass and gas mass relations as well as the total mass--temperature and Sunyaev-Zel'dovich flux--mass relations. Careful comparison of our results with scaling relations based on X-ray hydrostatic masses as opposed to weak lensing-derived masses reveals some discrepancies, which hint towards a non-negligible X-ray mass bias in observed samples. We further show that radial profiles of density, pressure and temperature of the simulated intracluster medium are in very good agreement with observations, in particular for $r > 0.3\ r_{500}$. In the innermost regions however we find too large entropy cores, which indicates that a more sophisticated modelling of the physics of AGN feedback may be required to accurately reproduce the observed populations of cool-core and non-cool-core clusters.