The XMM Cluster Outskirts Project (X-COP): Physical conditions to the virial radius of Abell 2142

TL;DR

This study combines SZ and X-ray data to analyze the thermodynamic properties of Abell 2142's outskirts, revealing the importance of accounting for gas clumping to accurately understand cluster physics.

Contribution

It introduces a clumping-insensitive method to recover gas density and demonstrates its impact on entropy and mass profiles in galaxy cluster outskirts.

Findings

Clumping explains observed entropy flattening in cluster outskirts.

Joint SZ/X-ray analysis yields mass profiles consistent with lensing and kinematics.

Proper accounting for clumping aligns thermodynamic profiles with gravitational collapse predictions.

Abstract

Context. Galaxy clusters are continuously growing through the accretion of matter in their outskirts. This process induces inhomogeneities in the gas density distribution (clumping) which need to be taken into account to recover the physical properties of the intracluster medium (ICM) at large radii. Aims. We studied the thermodynamic properties in the outskirts (R > R500) of the massive galaxy cluster Abell 2142 by combining the Sunyaev Zel'dovich (SZ) effect with the X-ray signal. Methods. We combined the SZ pressure profile measured by Planck with the XMM-Newton gas density profile to recover radial profiles of temperature, entropy and hydrostatic mass out to 2R500. We used a method that is insensitive to clumping to recover the gas density, and we compared the results with traditional X-ray measurement techniques. Results. When taking clumping into account, our joint SZ/X-ray entropy profile is consistent with the predictions from pure gravitational collapse, whereas a significant entropy flattening is found when the effect of clumping is neglected. The hydrostatic mass profile recovered using joint X-ray/SZ data agrees with that obtained from spectroscopic X-ray measurements and with mass reconstructions obtained through weak lensing and galaxy kinematics. Conclusions. We found that clumping can explain the entropy flattening observed by Suzaku in the outskirts of several clusters. When using a method insensitive to clumping for the reconstruction of the gas density, the thermodynamic properties of Abell 2142 are compatible with the assumption that the thermal gas pressure sustains gravity and that the entropy is injected at accretion shocks, with no need to evoke more exotic physics. Our results highlight the need for X-ray observations with sufficient spatial resolution, and large collecting area, to understand the processes at work in cluster outer regions.