Hyenas: X-ray Bubbles and Cavities in the Intra-Group Medium

TL;DR

This paper demonstrates that X-ray cavities and bubbles, generated by AGN feedback in cosmological simulations, can be observed and analyzed similarly to real data, providing new constraints on feedback models.

Contribution

It introduces the Hyenas simulation suite with realistic mock X-ray observations, showing cavities and bubbles consistent with observations, and evaluates feedback effects on the intra-group medium.

Findings

Cavities and bubbles are observable in simulations with properties matching real observations.

Cavity power can offset halo cooling, especially in low-mass halos.

Mechanical work in cavities occurs at lower pressures than the midpoint pressure.

Abstract

We investigate the role of the Simba feedback model on the structure of the Intra-Group Medium (IGrM) in the new Hyenas suite of cutting-edge cosmological zoom-in simulations. Using 34 high-resolution zooms of halos spanning from $10^{13}-10^{14}$ $M_\odot$ at $z=0.286$, we follow halos for 700 Myr, over several major active galactic nuclei (AGN) jet feedback events. We use the MOXHA package to generate mock Chandra X-ray observations, as well as predictive mocks for the upcoming LEM mission, identifying many feedback-generated features such as cavities, shock-fronts, and hot-spots, closely mimicking real observations. Our sample comprises $105$ snapshots with identified cavities, $50$ with single bubbles and $55$ with two, and spans three orders of magnitude in observed cavity enthalpies, from $10^{41}-10^{44}$ erg/s. Comparing semi-major axis length, midpoint radius, and eccentricity to a matched sample of observations, we find good agreement in cavity dimensions with real catalogues. We estimate cavity power from our mock maps following observational procedures, showing that this is typically more than enough to offset halo cooling, particularly in low-mass halos, where we match the observed excess in energy relative to cooling. Bubble enthalpy as measured with the usual midpoint pressure typically exceeds the energy released by the most recent jet event, hinting that the mechanical work is done predominantly at a lower pressure against the IGrM. We demonstrate for the first time that X-ray cavities are observable in a modern large-scale simulation suite and discuss the use of realistic cavity mock observations as new halo-scale constraints on feedback models in cosmological simulations.