Abstract
We present a novel quantitative scheme of cluster classification based on the morphological properties that are manifested in X-ray images. We use a conventional radial surface brightness concentration parameter (c_{SB}) as defined previously by others, and a new asymmetry parameter, which we define in this paper. Our asymmetry parameter, which we refer to as photon asymmetry ($A_{phot}), was developed as a robust substructure statistic for cluster observations with only a few thousand counts. To demonstrate that photon asymmetry exhibits better stability than currently popular power ratios and centroid shifts, we artificially degrade the X-ray image quality by: (a) adding extra background counts, (b) eliminating a fraction of the counts, (c) increasing the width of the smoothing kernel, and (d) simulating cluster observations at higher redshift. The asymmetry statistic presented here has a smaller statistical uncertainty than competing substructure parameters, allowing for low levels of substructure to be measured with confidence. A_{phot} is less sensitive to the total number of counts than competing substructure statistics, making it an ideal candidate for quantifying substructure in samples of distant clusters covering wide range of observational S/N. Additionally, we show that the asymmetry-concentration classification separates relaxed, cool core clusters from morphologically-disturbed mergers, in agreement with by-eye classifications. Our algorithms, freely available as Python scripts (https://github.com/ndaniyar/aphot) are completely automatic and can be used to rapidly classify galaxy cluster morphology for large numbers of clusters without human intervention.
Highlights
Clusters of galaxies are complex objects where many astrophysical processes are taking place
We present below a new substructure statistic that is superior based on the above requirements
An important test for any substructure statistic is its insensitivity to the observational S/N
Summary
Clusters of galaxies are complex objects where many astrophysical processes are taking place. Cluster classification based on X-ray morphology can help us understand the dominant physical processes in particular types of clusters, shed light on the cluster formation histories, and give new insights into the evolution of both the large-scale structure of the universe (Allen et al 2011) and the baryonic component of galaxy clusters (Bohringer & Werner 2010). Two distinctive features of galaxy clusters that are detectable in X-ray images are (1) cool cores (CCs) and (2) departure from axial symmetry, presumed to arise from galaxy cluster mergers. It is believed that these features emerge at different stages of cluster evolution and are outcomes of completely different physical processes that affect the entire intracluster medium (ICM). One important reason to classify cluster morphology is that we can explore any correlations between morphology and residuals in various cluster scaling relations, resulting in more robust estimates of, for example, galaxy cluster mass (M500)
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