XRISM collaboration

Galaxy clusters, the largest gravitationally bound structures in the Universe, contain vast amounts of dark matter, galaxies, and hot ionised gas known as the intracluster medium (ICM). In relaxed cluster cores, the ICM appears to cool radiatively faster than the age of the cluster, but the absence of line emission from the predicted cooling rate suggests heating mechanisms that offset the cooling, with feedback from active galactic nuclei (AGNs) being the most likely source. Turbulence and bulk motions, such as the oscillating (``sloshing'') motion of the core gas in the cluster potential well, have also been proposed as mechanisms for the distribution of heat from the outside of the core. Here we present high-resolution X-ray spectroscopic observations of the core of the Centaurus galaxy cluster with the XRISM satellite. We find that the hot gas is streaming along the line of sight relative to the central galaxy (NGC 4696), with relative velocities varying from 130 km/s to 310 km/s within ~ 30 kpc of the centre, indicating a structured bulk flow ("wind") blowing in the core. This wind is consistent with the core gas sloshing. While the wind may prevent excessive accumulation of cooled gas at the centre of the cluster, it could also distribute the heat injected by the central AGN and/or bring in thermal energy from the surrounding ICM, thus contributing to the thermal balance at the cluster centre. The velocity dispersion (turbulent velocity) of the gas is found to be only ~< 120 km/s (corresponding to a Mach number M ~< 0.2) in the core, even within ~ 10 kpc of the AGN. This may indicate that the influence of the AGN on the motion of the surrounding ICM is limited in the Centaurus cluster.