Merger Signatures in the Galaxy Cluster Abell 98

TL;DR

This study analyzes Chandra and XMM-Newton data of galaxy cluster Abell 98, revealing merger signatures, shock regions, AGN feedback effects, and large-scale filamentary structures, advancing understanding of cluster dynamics and interactions.

Contribution

It provides new evidence of merger activity, shock heating, AGN feedback, and filamentary gas in Abell 98, with detailed multi-wavelength analysis and dynamical modeling.

Findings

Evidence of shock-heated regions indicating early merger stages

Detection of cavities in the ICM linked to AGN activity

Identification of filamentary gas connecting subclusters

Abstract

We present results from Chandra and XMM-Newton observations of Abell 98 (A98), a galaxy cluster with three major components: a relatively bright subcluster to the north (A98N), a disturbed subcluster to the south (A98S), and a fainter subcluster to the far south (A98SS). We find evidence for surface brightness and temperature asymmetries in A98N consistent with a shock-heated region to the south, which could be created by an early stage merger between A98N and A98S. Deeper observations are required to confirm this result. We also find that A98S has an asymmetric core temperature structure, likely due to a separate ongoing merger. Evidence for this is also seen in optical data. A98S hosts a wide-angle tail (WAT) radio source powered by a central active galactic nucleus (AGN). We find evidence for a cavity in the intracluster medium (ICM) that has been evacuated by one of the radio lobes, suggesting that AGN feedback is operating in this system. Examples of cavities in non-cool core clusters are relatively rare. The three subclusters lie along a line in projection, suggesting the presence of a large-scale filament. We observe emission along the filament between A98N and A98S, and a surface brightness profile shows emission consistent with the overlap of the subcluster extended gas haloes. We find the temperature of this region is consistent with the temperature of the gas at similar radii outside this bridge region. Lastly, we examine the cluster dynamics using optical data. We conclude A98N and A98S are likely bound to one another, with a 67% probability, while A98S and A98SS are not bound at a high level of significance.