Substructures associated with the sloshing cold front in the Perseus cluster

TL;DR

This study analyzes X-ray substructures in the Perseus cluster's core, identifying Kelvin-Helmholtz instability layers and magnetic field effects, providing insights into intracluster medium microphysics and turbulence.

Contribution

It presents detailed analysis of cold front substructures, including the first candidate KHI layer and magnetic field-induced features, advancing understanding of ICM dynamics.

Findings

Identification of a Kelvin-Helmholtz instability layer candidate.

Estimated turbulent heating rate balancing radiative cooling.

Detection of feather-like structures consistent with magnetic field effects.

Abstract

X-ray substructures in clusters of galaxies provide indirect clues about the microphysical properties of the intracluster medium (ICM), which are still not very well known. In order to investigate X-ray substructures in detail, we studied archival $\sim$1~Msec Chandra data of the core of the Perseus cluster, focusing on the substructures associated with the sloshing cold front. In the east half of the cold front, we found a Kelvin-Helmholtz instability (KHI) layer candidate. The measured width-to-azimuthal extension ratio and the thermodynamic properties are all consistent with it being a KHI layer currently developing along the sloshing cold front. We found a thermal pressure deficit of the order of 10$^{-2}~\mathrm{keV~cm^{-3}}$ at the KHI layer. Assuming that turbulent pressure fully supports the pressure deficit, we estimated the turbulent strength at several hundred km~s$^{-1}$, which translates into the turbulent heating rate of $Q_\mathrm{turb}\sim 10^{-26}~\mathrm{erg~cm^{-3}~s^{-1}}$. This value agrees within an order of magnitude with the previous estimation derived from the surface brightness fluctuations, and can balance the radiative cooling at this radius. In the west half of the cold front, we found feather-like structures which are similar to the structures observed in recent numerical simulations of the gas sloshing of magnetized plasma. Their thermodynamic properties are consistent with one of the feathers being a projected gas depletion layer induced by the amplified magnetic field whose strength is $B\sim$30$~\mathrm{\mu G}$.