Beyond Self-Similarity: Reconciling X-Ray Scaling Relations in Galaxy Clusters and Groups

Abstract

Scaling relations hold among observed quantities that describe the thermodynamic properties of the gas in galaxy clusters and groups. However, observed data show systematic departures from the self-similar model's baseline predictions, particularly in lower-mass systems. I show that the observed departures from self-similar predictions can be efficiently described by two physical quantities modeled with power laws: the gas mass fraction (fg Tf1 Ezfz) and the temperature variation (fT Tt1 Eztz). Using a large variety of published X-ray scaling relations, this study proceeds with an MCMC-based meta-analysis to constrain the temperature- and redshift-dependence of the meta-parameters fg and fT to calibrate the model. These calibrations indicate that, while the gas mass fraction (fg) does not show significant evolution with cosmic time (fz = -0.11 0.03), it decreases significantly with decreasing halo mass (f1 = 0.50 0.01). On the other hand, the temperature variation shows a mild positive increase with both mass and redshift. Overall, modeling the departures from the self-similar model with \fg, fT\ drastically improves predictive accuracy, reducing the number of scaling relations in >3σ (>5 σ) tension from 49 (36) percent under the self-similar scenario to just 11 (3) percent (four and one out of 39, respectively) that might be identified for their peculiarity. Moreover, the modelization through the generalized form allows me to present an extended discussion of the expected slopes and redshift evolution for several X-ray scaling laws, including the new quantity YLGT0 = L-1 Mg2 T1/2, a proxy for the cluster's volume which does not depend on fg and fT by construction, and is predicted to relate directly to the mass without any redshift evolution: M YLGT0 fg0 fT0 Ez0.