The eROSITA Final Equatorial-Depth Survey (eFEDS): X-ray Properties and Scaling Relations of Galaxy Clusters and Groups

TL;DR

This study analyzes X-ray properties and scaling relations of 542 galaxy clusters and groups from the eFEDS survey, revealing significant deviations from self-similar models and emphasizing the role of non-gravitational physics.

Contribution

It provides the first comprehensive analysis of X-ray scaling relations in a large, low-mass galaxy cluster sample, accounting for selection effects and cosmic evolution.

Findings

Significant deviation of scaling relation slopes from self-similar predictions.

Good agreement with simulations including non-gravitational physics.

Demonstrates eROSITA's capability to measure ICM emission in low-mass clusters.

Abstract

We investigate the scaling relations between X-ray observables of the clusters detected in the eFEDS field using Spectrum-Roentgen-Gamma/eROSITA observations taking into account the selection effects and the distributions of observables with cosmic time. We extract X-ray observables (Lx, Lbol, T, Mgas, Yx) within R500 for the sample of 542 clusters in the eFEDS field. By applying detection and extent likelihoods, we construct a subsample of 265 clusters with a contamination level of <10% (including AGNs and spurious fluctuations) to be utilized in the scaling relation analysis. The selection function based on the state-of-the-art simulations of the eROSITA sky is fully accounted for in our work. We provide the X-ray observables in the core-included <R500 and core-excised 0.15*R500-R500 apertures for 542 galaxy clusters and groups detected in the eFEDS field. Additionally, we present our best-fit results for the normalization, slope, redshift evolution and intrinsic scatter parameters of the X-ray scaling relations between Lx-T, Lx-Mgas, Lx-Yx, Lbol-T, Lbol-Mgas, Lbol-Yx and Mgas-T. We find that the best-fit slopes significantly deviate from the self-similar model at a >3sigma confidence level however, our results are in good agreement with the simulations including non-gravitational physics and the recent results that take into account selection effects. Strong deviations we find from the self-similar scenario indicate that the non-gravitational effects play an important role in shaping the observed physical state of clusters. This work extends the scaling relations to low mass, low luminosity galaxy cluster and group regime using eFEDS observations, demonstrating eROSITA's ability to measure ICM emission out to R500 with survey-depth exposures and constrain the scaling relations in a wide mass-luminosity-redshift range.