http://arxiv.org/abs/2004.00021
Observations since the 1970’s have revealed the existence of cool-core (CC) clusters, which are galaxy clusters with a central cooling time much shorter than the age of the universe. Both observations and theory suggest that the ambient gas at the centers of galaxy clusters is thermally regulated by a central heating mechanism that suppresses condensation (most likely an active galactic nucleus, or AGN). Previous analytical work has suggested specific configurations of heating kernels that may result in thermal balance and a steady state. To test this hypothesis, we simulated idealized galaxy clusters using the ENZO cosmology code with a spatial heat-input kernel meant to mimic feedback from a central AGN. Thermal heating as a function of radius was injected according to a range of kernels, with global thermal balance enforced at all times. We compare our simulation results with observed entropy profiles from the ACCEPT cluster dataset. Although some heating kernels produced thermally steady galaxy clusters, no kernel was able to produce a steady cluster with a central entropy as low as the central entropies typically observed among CC clusters. The general behavior of the simulations depended on the amount of heating in the inner $10 ~\text{kpc}$, with low central heating leading to central cooling catastrophes, high central heating creating a central convective zone with an inverted entropy gradient, and intermediate heating leading to a flat but elevated entropy core. The simulated clusters enter an unsteady multiphase state on a timescale proportional to the square of the cooling time of the lowest entropy gas in the simulation, with centrally concentrated heating resulting in a steady state lasting for a longer period of time.
F. Glines, B. O’Shea and G. Voit
Thu, 2 Apr 20
46/56
Comments: 14 page, 8 figures
You must be logged in to post a comment.