On the coherent rotation of diffuse matter in numerical simulations of galaxy clusters

We analyse the dynamical properties of Intra-Cluster Medium (ICM) and dark matter (DM) in galaxy clusters to highlight the presence of coherent motions, in a volume-limited sample extracted from the gas-dynamical simulations of the MUSIC project. We select the most massive haloes and we use three different models to describe the physics of baryons: a non-radiative model, and two models including radiative physics, with and without the AGN feedback. We aim to get a statistics on the contribution from rotational motions to the dynamics of massive clusters, and to possibly characterize them through a suitable model. Our study is focused on the relaxed clusters (57 per cent of our total sample) that we classify as as rotating or non-rotating according to the gas spin parameter, finding that 4 per cent of the relaxed sample is rotating. We study the radial profiles of their specific angular momentum vector, finding that the solid body model is not suitable to describe a rotation. The radial profiles of the tangential and turbulent components of ICM and DM velocity highlight the dominant role of turbulence in the case of DM while for the gas we find a comparable contribution to that of coherent motions. The results suggest in general a co-rotation of ICM and DM, since their profiles show similarities and their angular momenta are correlated. The dominating role of DM in the dynamics is also supported by the lack of significant differences from the three different models describing the baryon physics.