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COSMOS Kyoto meeting May 2005 Obscured AGN in the COSMOS field Andrea Comastri (INAF – Bologna) on behalf of the XMM-COSMOS team
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COSMOS Kyoto meeting May 2005 High redshift obscured quasars - - Unbiased tracers of SMBH/Host Galaxy “Co-evolution” - - Obscured (hard) X—ray emission SMBH is present and the host galaxy is visible morphology of obscured AGN - - ACF - - Interactions
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COSMOS Kyoto meeting May 2005 Looking for obscured quasars: a combined Xray, optical, near infrared selection Selection of high-z obscured QSO: from X-ray + photo-z catalog optical-to-near-infrared color (R-K>4) X-ray-to-optical color (X/O>10) photometric redshift (zphot>1) ( adapted from Brusa et al. 2005) Shallow X-ray flux + large area pick-up the most extreme sources
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COSMOS Kyoto meeting May 2005 Luminosity vs. column density Spectral analysis of the brightest X-ray sources ~50% are indeed QSO2! adapted from Brusa et al. 2005
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COSMOS Kyoto meeting May 2005 X-ray emitting EROs at z~1.4 Average X-ray spectrum NH= 3. 10^22 L(X)= 10^44 The K-brightest objects will be observed with the low resolution IR (JHK) AMICI spectrograph at TNG
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COSMOS Kyoto meeting May 2005 Morphological test on primary/secondary identifications Most of the counterparts (~80%) of hard sources (undetected in the soft band)are extended (obscured nucleus both in X- ray and optical bands) and “reddish” ( ~60% with R-K>4; to be compared with 25% for the total number of primary IDs) with 0.8 <z phot < 1.8 ( ~ 70%) Excellent consistency between X-ray spectra and optical (ACS + color) data
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COSMOS Kyoto meeting May 2005 Angular Correlation Function in COSMOS The large connected area should allow the determination of the angular correlation function w(θ) = (θ/θ 0 ) -γ up to a large scale Complementary to Chandra data from which w(θ) is well measured for 5 < θ < 100 arcsec: γ ~ 1; θ 0 ~ 10 arcsec Giacconi et al. 2001 CDFS – 120 ksec
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COSMOS Kyoto meeting May 2005 Chandra (Yang et al. 2003) stronger signal in the hard band XMM 2dF Shallow Survey (1+1 deg2) Basilakos et al. 2004/2005
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COSMOS Kyoto meeting May 2005 Chandra (Yang et al. 2003) stronger signal in the hard band Θ (h) ~ 40+-11 Θ (s) ~ 4+-2 115 hard sources 298 soft sources XMM 2dF Shallow Survey (1+1 deg2) Basilakos et al. 2004/2005 Θ (h) ~ 22+-10 Θ (s) ~ 10+-2 171 hard sources 432 soft sources
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COSMOS Kyoto meeting May 2005 Angular Correlation Function in COSMOS: The Soft Sample Preliminary results on 12 XMM pointings : area ~ 1.3 sq. deg. Applying the Landy-Szalay and the Hamilton estimators (see Kerscher et al. 2000 for a comparison of the most widely used estimators) we find that : Soft sample (0.5 – 2.0 keV): About 650 sources – Signal for 20 < θ < 1250 arcsec (0.15 < d < 10 Mpc at z ~ 1) γ ~ 0.45 Θ 0 ~ 1.5 – 2.0 arcsec ( but based on significant extrapolation …) Cut due to integral constraint
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COSMOS Kyoto meeting May 2005 Angular Correlation Function in COSMOS: The Hard Sample About 310 sources Signal for 40 < θ < 1250 arcsec (0.3 < d < 10 Mpc at z ~ 1) γ ~ 0.55 Θ 0 ~ 4 - 5 arcsec Hard Soft Comparison between Hard and soft ACFs
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COSMOS Kyoto meeting May 2005 Angular Correlation Function in COSMOS: Preliminary conclusions Both soft and hard selected samples show significant correlation from 25 – 40 arcsec up to about 20 arcmin (limit due to the integral constraint) The slopes are somewhat flatter (γ ~ 0.5) than “canonical” values Θ 0 values ( ~ 1.5 arcsec (Soft) and ~ 4.5 arcsec (hard) ) are uncertain,but appear to be smaller than in CDFS The hard correlation function is somewhat higher than the soft one, but not yet statistically significant (due to different redshift distribution?)
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COSMOS Kyoto meeting May 2005 X-ray enhancement due to interactions? Are these objects in interaction? How many do we have in the X-ray sample? Examples of ACS images around X-ray sources : 2” radius
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COSMOS Kyoto meeting May 2005 X-ray enhancement due to interactions? Preliminary analysis (Vignali et al., in progress) on a sub- sample of XMM sources with an optical identification (~ 125/600 = 21 %) shows that the number of additional ACS sources within 2” is higher than in a comparison sample with the same magnitude distribution as the sample of optical IDs (51 vs 42) The excess of close pairs around X-ray sources is therefore 9 +- 7, not statistically significant, yet (to be completed on the total sample) In any case, this analysis suggests that possible effects relating X-ray enhancement to on-going interactions, if present, are effective for a small fraction (< 10% ?) of the X- ray sources.
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