The three hundred project: thermodynamical properties, shocks, and gas dynamics in simulated galaxy cluster filaments and their surroundings

ABSTRACT Using cosmological simulations of galaxy cluster regions from The Three Hundred project, we study the nature of gas in filaments feeding massive clusters. By stacking the diffuse material of filaments throughout the cluster sample, we measure average gas properties such as density, temperat...

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Bibliographic Details
Published in:Monthly notices of the Royal Astronomical Society 2024-01, Vol.527 (1), p.1301-1316
Main Authors: Rost, Agustín M, Nuza, Sebastián E, Stasyszyn, Federico, Kuchner, Ulrike, Hoeft, Matthias, Welker, Charlotte, Pearce, Frazer, Gray, Meghan, Knebe, Alexander, Cui, Weiguang, Yepes, Gustavo
Format: Article
Language:English
Subjects:
Dark matter
Entropy
Filaments
Galactic clusters
Galaxy distribution
Gas density
Gas dynamics
Mach number
Phase diagrams
Radial velocity
Rarefaction
Temperature
Temperature profiles
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Summary:ABSTRACT Using cosmological simulations of galaxy cluster regions from The Three Hundred project, we study the nature of gas in filaments feeding massive clusters. By stacking the diffuse material of filaments throughout the cluster sample, we measure average gas properties such as density, temperature, pressure, entropy and Mach number and construct one-dimensional profiles for a sample of larger, radially oriented filaments to determine their characteristic features as cosmological objects. Despite the similarity in velocity space between the gas and dark matter accretion patterns on to filaments and their central clusters, we confirm some differences, especially concerning the more ordered radial velocity dispersion of dark matter around the cluster and the larger accretion velocity of gas relative to dark matter in filaments. We also study the distribution of shocked gas around filaments and galaxy clusters, showing that the surrounding shocks allow an efficient internal transport of material, suggesting a laminar infall. The stacked temperature profile of filaments is typically colder towards the spine, in line with the cosmological rarefaction of matter. Therefore, filaments are able to isolate their inner regions, maintaining lower gas temperatures and entropy. Finally, we study the evolution of the gas density–temperature phase diagram of our stacked filament, showing that filamentary gas does not behave fully adiabatically through time but it is subject to shocks during its evolution, establishing a characteristic z = 0, entropy-enhanced distribution at intermediate distances from the spine of about $1{-}2\, h^{-1}\,$ Mpc for a typical galaxy cluster in our sample.
ISSN:0035-8711
1365-2966
DOI:10.1093/mnras/stad3208