High Resolution XMM-Newton Spectroscopy of the Cooling Flow Cluster A3112

TL;DR

This study uses high-resolution XMM-Newton spectroscopy to analyze the gas properties, metallicity gradients, and turbulence in the cool core and outskirts of galaxy cluster A3112, confirming mass scaling relations and constraining turbulence energy.

Contribution

It provides detailed measurements of elemental abundance profiles, gas mass fraction, and turbulence limits in A3112, utilizing advanced spectral analysis techniques and high-resolution data.

Findings

Iron and silicon show central abundance increase

No spectral evidence for gas below 1 keV in core

Turbulent motions contribute less than 6% to total energy

Abstract

We examine high signal to noise XMM-Newton European Photon Imaging Camera (EPIC) and Reflection Grating Spectrometer (RGS) observations to determine the physical characteristics of the gas in the cool core and outskirts of the nearby rich cluster A3112. The XMM-Newton Extended Source Analysis Software data reduction and background modeling methods were used to analyze the XMM- Newton EPIC data. From the EPIC data we find that the iron and silicon abundance gradients show significant increase towards the center of the cluster while the oxygen abundance profile is centrally peaked but has a shallower distribution than that of iron. The X-ray mass modeling is based on the temperature and deprojected density distributions of the intra-cluster medium determined from EPIC observations. The total mass of A3112 obeys the M-T scaling relations found using XMM-Newton and Chandra observations of massive clusters at R500. The gas mass fraction f_gas= 0.149^{+0.036}_{-0.032} at R500, is consistent with the seven-year WMAP results. The comparisons of line fluxes and flux limits on the Fe XVII and Fe XVIII lines obtained from high resolution RGS spectra indicate that there is no spectral evidence for cooler gas associated with the cluster with temperature below 1.0 keV in the central <38" (\sim 52 kpc) region of A3112. High resolution RGS spectra also yield an upper limit to the turbulent motions in compact core of A3112 (206 km/s). We find that the energy contribution of turbulence to total energy is less than 6 per cent. This upper limit is consistent with the amount of energy contribution measured in recent high resolution simulations of relaxed galaxy clusters.