Testing the Low-Mass End of X-Ray Scaling Relations with a Sample of Chandra Galaxy Groups

TL;DR

This study examines X-ray scaling relations in galaxy groups to determine if they differ from clusters, finding that some relations hold but show increased scatter and a possible break at low masses, influenced by baryonic physics.

Contribution

It provides a comprehensive analysis of X-ray scaling relations in galaxy groups, extending cluster relations to the low-mass regime and highlighting differences and the impact of baryonic physics.

Findings

Scaling relations in groups generally agree with clusters.

Steepening of the Lx-T relation below 3 keV.

Evidence of a break between groups and clusters affecting relations.

Abstract

Well-determined scaling relations between X-ray observables and cluster mass are essential for using large cluster samples for cosmology. Cluster relations such as the Lx-T, M-T, Lx-M relations, have been investigated extensively, however the question remains whether these relations hold true also for groups. Some evidence supports a break at low masses, possibly caused by the influence of non-gravitational physics on low-mass systems. The main goal of this work is to test scaling relations for the low-mass range to check whether there is a systematic difference between clusters and groups, and to extend this method of reliable cluster mass determination for future samples down to the group regime. We compiled a statistically complete sample of 112 X-ray galaxy groups, 26 with Chandra data. Temperature, metallicity, and surface brightness profiles were created, and used to determine the main physical quantities and scaling relations. We then compared the group properties to the HIFLUGCS clusters and other samples. We present profiles and scaling relations of the whole sample. T and Z profiles behave universally, except for the cores. The Lx-T, M-T, Lx-M, Mg-M, M-Yx, and Lx-Yx relations are in good agreement with clusters. The Lx-T relation steepens for T<3keV, which could point to a larger impact of heating mechanisms on cooler systems. We found a strong drop in the gas mass fraction below 1keV, which indicates the ICM is less dominant in groups and the galaxies have a stronger influence on the system. In all relations the intrinsic scatter for groups is larger, which appears not correlated with merger activity but could be due to scatter caused by baryonic physics in the group cores. We also demonstrate the importance of selection effects. We have found evidence for a similarity break between groups and clusters. However this does not have a strong effect on scaling relations.