Simulating Groups and the IntraGroup Medium: The Surprisingly Complex and Rich Middle Ground between Clusters and Galaxies

Oppenheimer, Benjamin D.; Babul, Arif; Bahé, Yannick M.; Butsky, Iryna S.; McCarthy, Ian G.

doi:10.3390/universe7070209

Cited by 70 publications

(57 citation statements)

References 410 publications

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“…The role of the AGN feedback in reproducing the observed properties of galaxy clusters have been confirmed in many other studies (e.g., McCarthy et al 2010, Fabjan et al 2010, Le Brun et al 2014, Gaspari et al 2014, McCarthy et al 2017. It is possible to obtain reasonable gas mass fractions with models without AGN feedback, but the f gas -T X relation is flatter than observed (see the reviews by Eckert et al 2021 andOppenheimer et al 2021 for more details). Reproducing the correct f gas -T X (or the M gas -M) relation is crucial for a proper comparison between observations and simulations.…”

Section: Comparison With Simulationssupporting

confidence: 59%

“…Reproducing the correct f gas -T X (or the M gas -M) relation is crucial for a proper comparison between observations and simulations. The gas fraction is found to be mass-dependent (e.g., Vikhlinin et al 2006, Gonzalez et al 2007, Pratt et al 2009, Eckert et al 2016; see also the reviews by Eckert et al 2021 andOppenheimer et al 2021). A lower gas fraction leads to lower luminosity and Y X parameter impacting the shape of the relations.…”

Section: Comparison With Simulationsmentioning

confidence: 94%

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Scaling relations of clusters and groups, and their evolution

Lovisari¹,

Maughan²

2022

Preprint

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X-ray observations of the hot intra-cluster medium (ICM) in galaxy groups and clusters provide quantities such as their gas mass, X-ray luminosity, and temperature. The analysis of the scaling relations between these observable properties gives considerable insight into the physical processes taking place in the ICM. Furthermore, an understanding of the scaling relations between ICM properties and the total cluster mass is essential for cosmological studies with clusters. For these reasons, the X-ray scaling relations of groups and clusters have been a major focus of research over the past several decades. In this Chapter, after presenting the expectations from the self-similar model, based on the assumption that only gravity drives the evolution of the ICM, we discuss how the processes of gas cooling and non-gravitational heating are believed to be responsible for the observed deviations from the self-similar scenario. We also describe important complications that must be considered when measuring and interpreting the scaling relations.

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Section: Comparison With Simulationssupporting

confidence: 59%

Section: Comparison With Simulationsmentioning

confidence: 94%

Scaling relations of clusters and groups, and their evolution

Lovisari¹,

Maughan²

2022

Preprint

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“…So far, the main limitation to study simulated groups of galaxies in more detail has been the lack of simulations within cosmological context able to consistently resolve and match the stellar and gas properties of massive galaxy clusters and galaxies, simultaneously. Groups, in this respect, have often rather served as crucial testbed for assessing the prediction power of physical models embedded into cosmological simulations, especially related to feedback from central galaxies (see the companion reviews by Oppenheimer et al (2021) and Eckert et al (2021)). Nonetheless, given the recent encouraging results obtained on the chemical and thermal properties of the diffuse gas in various cosmic structures, especially with improvements in the description of chemo-energetic feedback from galaxies in group and cluster cores, more dedicated studies specifically focusing on the group regime in cosmological simulations are definitely needed to explore the details of their formation and evolution.…”

Section: Results From Cosmological Simulationsmentioning

confidence: 99%

“…Given their special position at the crossroad between smaller-scale physics and cosmic evolution, galaxy groups represent in fact a rather challenging, albeit crucial, target: capturing correctly the effects of feedback from central galaxies and BHs, given the shallower potential wells of groups compared to clusters, is of great importance. This has been in fact the main source of discrepancy in the comparison with observational findings, and consequently one of the crucial testbeds for cosmological simulations and the physical models therein included (for a thorough discussion, see the companion review by Oppenheimer et al, 2021).…”

Section: Cosmological Simulations and Large-scale Evolutionmentioning

confidence: 99%

“…The purpose of this paper is to review the status of the metal abundance measurements in the IGrM and the progress made by simulations to reproduce and interpret those measurements. It is a companion of the other reviews in this series addressing the scaling relations of these systems (Lovisari et al, 2021), the impact of AGN feedback (Eckert et al, 2021), the overall insight provided by simulations (Oppenheimer et al, 2021) and the properties of the particular class of fossil groups (Aguerri & Zarattini, 2021).…”

Section: Introductionmentioning

confidence: 99%

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The metal content of the hot atmospheres of galaxy groups

Gastaldello,

Simionescu,

Mernier

et al. 2021

Preprint

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Galaxy groups host the majority of matter and more than half of all the galaxies in the Universe. Their hot (10 7 K), X-ray emitting intra-group medium (IGrM) reveals emission lines typical of many elements synthesized by stars and supernovae. Because their gravitational potentials are shallower than those of rich galaxy clusters, groups are ideal targets for studying, through X-ray observations, feedback effects, which leave important marks on their gas and metal contents. Here, we review the history and present status of the chemical abundances in the IGrM probed by X-ray spectroscopy. We discuss the limitations of our current knowledge, in particular due to uncertainties in the modeling of the Fe-L shell by plasma codes, and coverage of the volume beyond the central region. We further summarize the constraints on the abundance pattern at the group mass scale and the insight it provides to the history of chemical enrichment. Parallel to the observational efforts, we review the progress made by both cosmological hydrodynamical simulations and controlled high-resolution 3D simulations to reproduce the radial distribution of metals in the IGrM, the dependence on system mass from group to cluster scales, and the role of AGN and SN feedback in producing the observed phenomenology. Finally, we highlight future prospects in this field, where progress will be driven both by a much richer sample of X-ray emitting groups identified with eROSITA, and by a revolution in the study of X-ray spectra expected from micro-calorimeters onboard XRISM and ATHENA.

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Scaling Relations of Clusters and Groups and Their Evolution

Lovisari

Maughan

2022

Handbook of X-Ray and Gamma-Ray Astrophysics

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Simulating Groups and the IntraGroup Medium: The Surprisingly Complex and Rich Middle Ground between Clusters and Galaxies

Cited by 70 publications

References 410 publications

Scaling relations of clusters and groups, and their evolution

Scaling relations of clusters and groups, and their evolution

The metal content of the hot atmospheres of galaxy groups

Scaling Relations of Clusters and Groups and Their Evolution

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