Exploring the relation between turbulent velocity and density fluctuations in the stratified intracluster medium

TL;DR

This study uses cosmological simulations to analyze the relationship between turbulent velocity and density fluctuations in the stratified intracluster medium, highlighting the influence of radial accretion and stratification on turbulence characteristics.

Contribution

It provides new insights into the relation between density and velocity fluctuations in the ICM, emphasizing the impact of stratification and radial accretion on turbulence properties.

Findings

Density and velocity fluctuations are related with a different slope than previously reported.

Radial accretion significantly influences gas fluctuations in the ICM.

Velocity and density spectra slopes are consistent across different cluster radii.

Abstract

The dynamics of the intracluster medium (ICM) is affected by turbulence driven by several processes, such as mergers, accretion and feedback from active galactic nuclei. X-ray surface brightness fluctuations have been used to constrain turbulence in galaxy clusters. Here, we use simulations to further investigate the relation between gas density and turbulent velocity fluctuations, with a focus on the effect of the stratification of the ICM. In this work, we studied the turbulence driven by hierarchical accretion by analysing a sample of galaxy clusters simulated with the cosmological code ENZO. We used a fixed scale filtering approach to disentangle laminar from turbulent flows. In dynamically perturbed galaxy clusters, we found a relation between the root mean square of density and velocity fluctuations, albeit with a different slope than previously reported. The Richardson number is a parameter that represents the ratio between turbulence and buoyancy, and we found that this variable has a strong dependence on the filtering scale. However, we could not detect any strong relation between the Richardson number and the logarithmic density fluctuations, in contrast to results by recent and more idealised simulations. In particular, we find a strong effect from radial accretion, which appears to be the main driver for the gas fluctuations. The ubiquitous radial bias in the dynamics of the ICM suggests that homogeneity and isotropy are not always valid assumptions, even if the turbulent spectra follow Kolmogorov's scaling. Finally, we find that the slope of the velocity and density spectra are independent of cluster-centric radii.