1. The zCOSMOS 3D density field Katarina Kovač 1, Simon Lilly 1, C. Porciani 1, O. Cucciati 2, A. Iovino 2, C. Knobel 1, C.M. Carollo 1, P. Oesch 1, A. Finoguenov 3 and the zCOSMOS team* *The zCOSMOS team comprises over 50 scientists; the main institutes involved are 1 ETH Zürich, LAM Marseille, 2 INAF Milan, Univ. Bologna, 3 MPE Garching and LAOMP Toulouse

2. zCOSMOS (600 hrs on VLT, started April 2005): - in the COSMOS field -about 20,000 spectra 0.1 < z < 1.4 in “- bright”: I AB < 22.5 over 1.7 deg 2 -about 10,000 spectra 1.4 < z < 3.5 in “- deep”: colour-selection, B < 25, over 0.9 deg 2 -designed for high success rate (~ 90% in bright, ~ 80% in deep) -and high sampling rate (~ 70%) with multiple passes (8 in bright, 4 in deep) -with velocity accuracy of 100 kms -1 in bright, 300 kms -1 in deep -duplication in spectral data reduction, redshift identification and other measurements 2’ 6.5’ 7.5’

3. Despite already covering most of the COSMOS field, the N(z) is very highly structured to z ~ 1: zCOSMOS - observations so far Currently, about 10000 spectra (10k “observed” sample) of the zCOSMOS-bright survey are reduced, from the underlying sample of about 40000 galaxies with I AB < 22.5 mag (40k “parent” sample), or about 110000 galaxies with I AB < 24 mag (100k sample).

4. 10k spectroscopic verification and photo-z consistency (1)593 repeated spectra  probabilistic verification of spectroscopic Confidence Classes plus measurement of velocity accuracy  v = 108 kms -1 (2)Comparison with photo-z (ZEBRA: Capak 2006 catalogue (old K)+IRAC, calibrated on old 1k sample):  z = 0.03(1+z). Class % of sample spectral verification photo-z consistency 428%99.6%96.4% 334%99.9%95.5% 215%92%93% one line6.4%90%95% 19.4%72%73% 07.8%-- Redshift reliability => 85% reliable redshifts

5. Reconstruction of the galaxy density field: ● One of the major goals of the zCOSMOS survey is to study galaxy environments, ranging from the scales of 100 kpc (galaxy groups) to the scales of 100Mpc. We use both galaxies with the spectroscopic and photometric redshifts to reliable reconstruct the broad range of environments. ● galaxies are correlated! ● ZADE approach: use the nearby spectro-z objects to modify photo-z P(z) of the rest of the population: PZ(z)dz = Nspec (R<RZADE)* P(z)dz / ∫P(z)dz

6. I AB < 22.5 mag red: ZEBRA output blue: RZADE <= 1 Mpc/h black: RZADE <= 5 Mpc/h magenta: RZADE <= 10 Mpc/h ZADE in work

7. Density estimate:  on a grid, counting the n-nearest neighbours all (parts of) galaxies within +/- 1000 km/s  n = n(+1)/S n ; S n = (D n ) 2  RZADE = 5 Mpc/h Testing the method

8. Testing the method – cont.

10. zCOSMOS (over)density field

25. 

26. Density-colour relation Complete sample: M B > -20-z

27. Density-morphology relation Complete sample: M B > -20-z ZEST morphologies (Scarlata et al. 2007) Also Tasca et al. in prep.

28. Conclusions ● zCOSMOS so far: 10000 spectra, high reliability 85% ● ZADE approach able to reproduce structures on a large range of scales ● ZADE advantage over 10k: smaller N, no need to model the complicated 10k sampling and z-success functions ● ZADE works also with the fixed apertures; and using the fainter galaxies ● Density-colour and density-morphology relations hold up-to higher redshifts (z~0.5 at least) ● Exploration: 1) properties of galaxies as a function of environment 2) galaxy – dark matter bias 3) structure extraction