Evolution in the iron abundance of the ICM
Abstract
We present a Chandra analysis of the X-ray spectra of 56 clusters of galaxies at z>0.3, which cover a temperature range of 3> kT > 15 keV. Our analysis is aimed at measuring the iron abundance in the ICM out to the highest redshift probed to date. We find that the emission-weighted iron abundance measured within (0.15-0.3) Rvir in clusters below 5 keV is, on average, a factor of 2 higher than in hotter clusters, following Z(T) 0.88 T-0.47 Z, which confirms the trend seen in local samples. We made use of combined spectral analysis performed over five redshift bins at 0.3> z > 1.3 to estimate the average emission weighted iron abundance. We find a constant average iron abundance ZFe 0.25 Z as a function of redshift, but only for clusters at z>0.5. The emission-weighted iron abundance is significantly higher (ZFe0.4 Z) in the redshift range z0.3-0.5, approaching the value measured locally in the inner 0.15 Rvir radii for a mix of cool-core and non cool-core clusters in the redshift range 0.1<z<0.3. The decrease in ZFe with z can be parametrized by a power law of the form (1+z)-1.25. The observed evolution implies that the average iron content of the ICM at the present epoch is a factor of 2 larger than at z 1.2. We confirm that the ICM is already significantly enriched (ZFe0.25 Z) at a look-back time of 9 Gyr. Our data provide significant constraints on the time scales and physical processes that drive the chemical enrichment of the ICM.
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