We present the analysis of the X-ray spectra of 18 distant clusters of galaxies with redshift 0.3 < z < 1.3. Most of them were observed with the Chandra satellite in long exposures ranging from 36 to 180 ks. For two of the z > 1 clusters, we also use deep XMM-Newton observations. Overall, these clusters probe the temperature range 3 keV less than or similar to kT less than or similar to 8 keV. Our analysis is aimed at deriving the iron abundance in the intracluster medium (ICM) out to the highest redshifts probed to date. Using a combined spectral fit of cluster sub-samples in different redshift bins, we investigate the evolution of the mean ICM metallicity with cosmic epoch. We find that the mean Fe abundance at [z] = 0.8 is Z = 0.25(-0.06)(+0.04) Z., consistent with the local canonical metallicity value, Z similar or equal to 0.3 Z., within the 1 sigma confidence level (c.l.). Medium- and low-temperature clusters (kT < 5 keV) tend to have larger iron abundances than hot clusters. At redshift [z] &SIM; 1.2 (four clusters at z > 1), we obtain a statistically significant detection of the Fe K line in only one cluster (Z > 0.10 Z. at the 90% c.l.). Combining all the current data sets from Chandra and XMM at z > 1, the average metallicity is measured to be [Z] = 0.21(-0.05)(+0.10) Z. (1 sigma error), thus suggesting no evolution of the mean iron abundance out to z similar or equal to 1.2.

Iron abundance in the intracluster medium at high redshift

ROSATI, Piero;
2003

Abstract

We present the analysis of the X-ray spectra of 18 distant clusters of galaxies with redshift 0.3 < z < 1.3. Most of them were observed with the Chandra satellite in long exposures ranging from 36 to 180 ks. For two of the z > 1 clusters, we also use deep XMM-Newton observations. Overall, these clusters probe the temperature range 3 keV less than or similar to kT less than or similar to 8 keV. Our analysis is aimed at deriving the iron abundance in the intracluster medium (ICM) out to the highest redshifts probed to date. Using a combined spectral fit of cluster sub-samples in different redshift bins, we investigate the evolution of the mean ICM metallicity with cosmic epoch. We find that the mean Fe abundance at [z] = 0.8 is Z = 0.25(-0.06)(+0.04) Z., consistent with the local canonical metallicity value, Z similar or equal to 0.3 Z., within the 1 sigma confidence level (c.l.). Medium- and low-temperature clusters (kT < 5 keV) tend to have larger iron abundances than hot clusters. At redshift [z] &SIM; 1.2 (four clusters at z > 1), we obtain a statistically significant detection of the Fe K line in only one cluster (Z > 0.10 Z. at the 90% c.l.). Combining all the current data sets from Chandra and XMM at z > 1, the average metallicity is measured to be [Z] = 0.21(-0.05)(+0.10) Z. (1 sigma error), thus suggesting no evolution of the mean iron abundance out to z similar or equal to 1.2.
2003
Tozzi, P; Rosati, Piero; Ettori, S; Borgani, S; Mainieri, V; Norman, C.
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11392/1854093
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