Abstract

We demonstrate a novel technique for calibrating the energy scale of the EPIC-pn detector onXMM-Newton, which allows us to measure bulk flows in the intracluster medium (ICM) of the Perseus and Coma galaxy clusters. The procedure uses the fluorescent instrumental background lines present in all observations, in particular, Cu-Kα. By studying their spatial and temporal variations, in addition to incorporating calibration observations, we refined the absolute energy scale of the detector to better than 150 km s−1at the Fe-K line, a large improvement over the nominal calibration accuracy of 550 km s−1. With our calibration, we mapped the bulk motions over much of the central 1200 and 800 kpc of Perseus and Coma, respectively, in spatial regions down to 65 and 140 kpc size. We cross-checked our procedure by comparing our measurements with those found in Perseus byHitomifor an overlapping 65 kpc square region, finding consistent results. For Perseus, there is a relative line-of-sight velocity increase of 480 ± 210 km s−1(1σ) at a radius of 250 kpc east of the nucleus. This region is associated with a cold front, providing direct evidence of the ICM sloshing in the cluster potential well. Assuming the intrinsic distribution of bulk motions is Gaussian, its width is 214 ± 85 km s−1, excluding systematic uncertainties. Removing the sloshing region, this is reduced to 20–150 km s−1, which is similar in magnitude to theHitomiline width measurements in undisturbed regions. In Coma, the line-of-sight velocity of the ICM varies between the velocities of the two central galaxies. Maps of the gas velocity and metallicity provide clues about the merger history of the Coma, with material to the north and east of the cluster core having a velocity similar toNGC 4874, while that to the south and west has velocities close toNGC 4889. Our results highlight the difference between a merging system, such as Coma, where we observe a ∼1000 km s−1range in velocity, and a relatively relaxed system, such as Perseus, with much weaker bulk motions.

Highlights

  • The velocity structure of the intracluster medium (ICM), the dominant baryonic component of galaxy clusters, remains poorly observationally constrained except in the core of the Perseus cluster (Hitomi Collaboration 2016, hereafter H16)

  • We demonstrate a novel technique for calibrating the energy scale of the European Photon Imaging Camera (EPIC)-pn detector on XMM-Newton, which allows us to measure bulk flows in the intracluster medium (ICM) of the Perseus and Coma galaxy clusters

  • Owing to the lower total number of counts in the Fe-K complex in Coma compared to Perseus, we split the cluster into 11 regions, with ten in the centre and one in the merging NGC 4839 group (Fig. 19 left panel)

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Summary

Introduction

The velocity structure of the intracluster medium (ICM), the dominant baryonic component of galaxy clusters, remains poorly observationally constrained except in the core of the Perseus cluster (Hitomi Collaboration 2016, hereafter H16). Simulations predict that the ICM should contain turbulent or random motions, and bulk flows caused by the merger of other clusters and subcomponents The material at smaller radius with lower temperature appears to have a low negative velocity, while the hotter gas outside this radius has a high positive velocity. This cooler material has a spiral-like twisted structure. Such structures are seen in simulations of ICM sloshing in cluster potential wells. The surface brightness residuals, temperature and velocity have similar morphologies to what we see in Perseus, and are indicative of sloshing, the simulations are not an exact match to what is observed

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Conclusion

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