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The XMM Distant Cluster Project: Survey limits and Pilot Survey Georg Lamer A. Schwope, V. Hambaryan, M. Godolt (AIP) H. Böhringer, R. Fassbender, P. Schücker, J. Santos (MPE) C. Mullis (U Michigan), P. Rosati (ESO)
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1.Extended source detection and survey sensitivity 2.X-ray redshifts 3. First results from pilot survey
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Rosati et al. 2002 Motivations for a z>1 cluster survey Existing samples mostly at z<1 Significance for cosmology: –Evolution of cluster luminosity function puts strong constraints on m Mullis et al. 2003
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Motivations for a z>1 cluster survey Existing samples mostly at z<1 Significance for cosmology: –Evolution of cluster luminosity function puts strong constraints on m Allen et al. 2004 High z samples needed for the investigation of –the cluster galaxy evolution –the evolution of the intracluster medium –Constraints on dark energy by measuring distances via the cluster gas fraction (cf talk by Stefano Ettori on caveats)
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X-ray surveys for clusters of galaxies XMM serendipity survey Rosati et al. 2002
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XMM serendipity survey ~4000 archived observations 0.15 deg 2 FOV High sensitivity 10 -15..10 -14 erg/(cm 2 s) resolve even most distant clusters Almost all extended sources are clusters
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Source detection pipeline EPIC images eexpmap exposure maps Standard XMM-SAS detection tasks Similar setup as for 2XMM catalogue eboxdetect esplinemap background maps eboxdetect emldetect PSF fiiting
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Source detection pipeline emldetect: Fitting PSF folded with King profile
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Verification of survey limits Simulation of XMM EPIC data: –Simulate 100 source lists with AGN logN-logS (Hasinger & Brandt 2005) + cluster logN – logS (Rosati et al. 1998) –Create simulated EPIC images in 3 x 5 energy bands (typical background, 20 ksec exposure). Run source detection pipeline on fake data sets.
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Verification of survey limits
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Detected fraction: ~50% @ f=10 -14 Spurious fraction (before visual screening)
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X-ray redshifts Possibility of measuring redshifts from X-ray spectra? Extracted spectra of 90 clusters with > 500 counts, calculating grid of MEKAL models in T-z plane (Master thesis M. Godolt). Mekal redshift=0.8 kT= 4.0
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X-ray redshifts Determined 17 redshifts (mostly low T clusters @ z< 0.5)
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X-ray redshifts Newly discovered cluster @ z=0.8: Subaru I-band
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Pilot cluster survey Survey area: 9 deg 2 at sensitivity 7x10 -15 cgs Best sensitivity:10 -15 cgs Detected 155 extended sources Optical follow up in ESO P72 / P73 (2003/2004)
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Optical follow up observations Select high redshift cluster candidates using DSS images –Eliminate non-cluster identifications –Select DSS blank fields for R + z band imaging with VLT FORS2 VLT imaging in R + z bands (47 candidates) –Estimate photometric redshifts Spectroscopic confirmation (VLT FORS 2)
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Selecting blank DSS fields
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EPIC DSS2
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VLT imaging Imaging observations with FORS 2: R and z bands R lim > 24.5, z lim > 23 m Determine R-z colours cluster red sequence redshift estimate. z~1.2
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Pilot survey: Results Photometric (R-z) redshifts 10
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RzK composite
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XMMU J2235-2557 z = 1.39 Mullis et al. 2005
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XMMU J2235-2557 fact sheet f X = 3.6 x 10 -14 erg/(cm 2 s) L X = 3 x 10 44 h 70 -2 erg/s (0.5 – 2.0 keV) kT = 6 +2.5 -1.8 keV (280 photons) M ~ 5 x 10 14 M sun Cluster red sequence: R – z ~ 2.1 12 redshifts between 1.38 and 1.40: = 1.393 Velocity dispersion: 760 +- 265 km/s Follow-up observations with Chandra, XMM, Spitzer, HST...
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Conclusions & Outlook Survey sensitivity well described by simulations. Limited possibility to obtain redshifts from XMM spectra. Pilot survey demonstrated efficient strategy to find distant clusters ~ 1/4 of new XMM clusters at z > 0.5 ~ 1/4 of these have z > 1.0 XMM 2235-2557: X-ray luminous cluster at z=1.39 Next goal: sample of 30 clusters at z >1
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