CLASH-X: A Comparison of Lensing and X-ray Techniques for Measuring the Mass Profiles of Galaxy Clusters [CEA]

http://arxiv.org/abs/1405.7876


We present profiles of temperature, gas mass, and hydrostatic mass estimated from X-ray observations of CLASH clusters. We compare measurements from XMM and Chandra and compare both sets to CLASH gravitational lensing mass profiles. We find that Chandra and XMM measurements of electron density and enclosed gas mass as functions of radius are nearly identical, indicating that any differences in hydrostatic masses inferred from X-ray observations arise from differences in gas-temperature estimates. Encouragingly, gas temperatures measured in clusters by XMM and Chandra are consistent with one another at ~100 kpc radii but XMM temperatures systematically decline relative to Chandra temperatures as the radius of the temperature measurement increases. One plausible reason for this trend is large-angle scattering of soft X-ray photons in excess of that amount expected from the standard XMM PSF correction. We present the CLASH-X mass-profile comparisons in the form of cosmology-independent and redshift-independent circular-velocity profiles, which are the most robust way to assess mass bias. Chandra HSE mass to CLASH lensing mass ratio profiles show no obvious radial dependence in the 0.3-0.8 Mpc range. However, the mean mass biases inferred from the WL and SaWLens data are different, with a weighted-mean value at 0.5 Mpc of <b>=0.12 for the WL comparison and <b>= -0.11 for the SaWLens comparison. XMM HSE mass to CLASH lensing mass ratio profiles show a pronounced radial dependence in the 0.3-1.0 Mpc range, with a weighted-mean mass bias of value rising to b>0.3 at ~1 Mpc for the WL comparison and b~0.25 for the SaWLens comparison. The enclosed gas mass profiles from both Chandra and XMM rise to a value ~1/8 times the total-mass profiles inferred from lensing at ~0.5 Mpc, suggesting that 8 M_gas profiles may be an excellent proxy for total-mass profiles at >~0.5 Mpc in massive galaxy clusters.

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M. Donahue, G. Voit, A. Mahdavi, et. al.
Mon, 2 Jun 14
52/56

Comments: Submitted to ApJ