Predicting the Non-Thermal Pressure in Galaxy Clusters

Abstract

We investigate the relationship between a galaxy cluster's hydrostatic equilibrium state, the entropy profile, K, of the intracluster gas, and the system's non-thermal pressure (NTP), within an analytic model of cluster structures. When NTP is neglected from the cluster's hydrostatic state, we find that the gas' logarithmic entropy slope, k d K/d r, converges at large halocentric radius, r, to a value that is systematically higher than the value k1.1 that is found in observations and simulations. By applying a constraint on these `pristine equilibrium' slopes, keq, we are able to predict the required NTP that must be introduced into the hydrostatic state of the cluster. We solve for the fraction, F pnt/p, of NTP, pnt, to total pressure, p, of the cluster, and we find F(r) to be an increasing function of halocentric radius, r, that can be parameterised by its value in the cluster's core, F0, with this prediction able to be fit to the functional form proposed in numerical simulations. The minimum NTP fraction, as the solution with zero NTP in the core, F0=0, we find to be in excellent agreement with the mean NTP predicted in non-radiative simulations, beyond halocentric radii of r0.7r500, and in tension with observational constraints derived at similar radii. For this minimum NTP profile, we predict F0.20 at r500, and F0.34 at 2r500; this amount of NTP leads to a hydrostatic bias of b0.12 in the cluster mass M500 when measured within r500. Our results suggest that the NTP of galaxy clusters contributes a significant amount to their hydrostatic state near the virial radius, and must be accounted for when estimating the cluster's halo mass using hydrostatic equilibrium approaches.