Probable Detection of a Cooler Gas Component in the Perseus Cluster with XRISM

Abstract

We present an analysis of the temperature structure of the Perseus cluster atmosphere using XRISM Resolve observations. The average temperature rises from 3.3 keV near the nucleus of NGC 1275 to 8 keV at 10 arcmin (210 kpc), which is consistent with Chandra and XMM measurements. The velocity and velocity dispersion profiles are broadly consistent with those in arXiv:2509.04421. While the gas at altitudes beyond 60 kpc can be modeled as a single temperature plasma, we find evidence for more than one gas phase in the inner 60 kpc. The hotter gas component, traced primarily by the Fe Heα line, has a velocity dispersion of 140 km s-1. We detect a cooler, 1.87-2.43 keV, gas component with a velocity dispersion of 300-400 km s-1 and a bulk velocity of 21-213 km s-1 with respect to the central galaxy. These ranges reflect large systematic uncertainties associated with modeling spatial-spectral mixing and the bright central point source. Potential low energy gain variations may add additional uncertainties. The cooler component is identified by broad wings in prominent emission lines, most notably S Lyα and Fe Heα. This cooler component's Mach number 0.73-0.96 and non-thermal pressure fraction of 22.9-33.7\% are much higher than found for the hotter gas. The cooler gas may be associated with merging halos along the line of sight which formed the cool, sloshing spiral and/or cooling gas being disturbed by the radio jets and lobes.