The case for large-scale AGN feedback in galaxy formation simulations: insights from XFABLE

TL;DR

This paper demonstrates that large-scale AGN radio-mode feedback models, especially those with jets thermalizing at large distances, align well with observational constraints and improve galaxy formation simulations.

Contribution

It introduces the XFABLE model with large-scale jet feedback, showing its consistency with multiple observational data and emphasizing the need for more realistic black hole feedback physics.

Findings

XFABLE model agrees with weak lensing and kSZ constraints across all scales.

The model maintains consistency with galaxy stellar mass functions and gas fractions.

Large-scale jet feedback improves simulation accuracy for galaxy and cluster properties.

Abstract

While cosmological simulations of galaxy formation have reached maturity, able to reproduce many fundamental galaxy and halo properties, no consensus has yet been reached on the impact of `baryonic feedback' on the non-linear matter power spectrum. This severely limits the precision of (and potentially biases) small-scale cosmological constraints obtained from weak lensing and galaxy surveys. Recent observational evidence indicates that `baryonic feedback' may be more extreme than commonly assumed in current cosmological hydrodynamical simulations. In this paper, we therefore explore a range of empirical AGN feedback models, within the FABLE simulation suite, with different parameterizations as a function of cosmic time, host halo properties, and/or spatial location where feedback energy is thermalized. We demonstrate that an AGN radio-mode feedback acting in a larger population of black holes, with jets thermalizing at relatively large cluster-centric distances, as exemplified by our XFABLE model, is in good agreement with the latest weak lensing + kSZ constraints across all k-scales. Furthermore, XFABLE maintains good agreement with the galaxy stellar mass function, gas fraction measurements, and all key galaxy group and cluster properties, including scaling relations and ICM radial profiles. Our work highlights the pressing need to model black hole accretion and feedback physics with a greater level of realism, including relativistic, magnetized jets in full cosmological simulations. Finally, we discuss how a range of complementary observational probes in the near future will enable us to constrain AGN feedback models, and therefore reduce `baryonic feedback' modelling uncertainty for the upcoming era of large cosmological surveys.