Large Structures and Galaxy Evolution in COSMOS at
                    <i>z</i>
                    &lt; 1.1

Scoville, N. Z.; Aussel, H.; Benson, Andrew; Blain, A. W.; Calzetti, D.; Capak, P.; Ellis, Richard S.; El-Zant, Amr; Finoguenov, A.; Giavalisco, Mauro; Guzzo, L.; Hasinger, G.; Koda, Jin; Fèvre, O. Le; Massey, Richard; McCracken, H. J.; Mobasher, Bahram; Renzini, A.; Rhodes, Jason; Salvato, M.; Sanders, D. B.; Sasaki, S.; Schinnerer, E.; Sheth, Kartik; Shopbell, P. L.; Taniguchi, Yoshiaki; Taylor, James E.; Thompson, D. J.

doi:10.1086/516751

Cited by 167 publications

(154 citation statements)

References 74 publications

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“…We note that for ξ − the signal is somewhat low for lower redshift combinations (smaller ξ kl,mod ± ), whereas it is slightly increased compared to predictions at higher redshifts. This behaviour is not surprising as most massive structures in COSMOS are located at 0.7 < ∼ z < ∼ 0.9 (Scoville et al 2007b), which create a lensing signal only for the higher redshift source bins. Slight differences between ξ + and ξ − are also expected, given that they probe the power spectrum with different filter functions, see Eq.…”

Section: Redshift Scaling Of Shear-shear Cross-correlationsmentioning

confidence: 88%

Evidence of the accelerated expansion of the Universe from weak lensing tomography with COSMOS

Schrabback

Hartlap

Joachimi

et al. 2010

A&A

340

454

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We present a comprehensive analysis of weak gravitational lensing by large-scale structure in the Hubble Space Telescope Cosmic Evolution Survey (COSMOS), in which we combine space-based galaxy shape measurements with ground-based photometric redshifts to study the redshift dependence of the lensing signal and constrain cosmological parameters. After applying our weak lensingoptimized data reduction, principal-component interpolation for the spatially, and temporally varying ACS point-spread function, and improved modelling of charge-transfer inefficiency, we measured a lensing signal that is consistent with pure gravitational modes and no significant shape systematics. We carefully estimated the statistical uncertainty from simulated COSMOS-like fields obtained from ray-tracing through the Millennium Simulation, including the full non-Gaussian sampling variance. We tested our lensing pipeline on simulated space-based data, recalibrated non-linear power spectrum corrections using the ray-tracing analysis, employed photometric redshift information to reduce potential contamination by intrinsic galaxy alignments, and marginalized over systematic uncertainties. We find that the weak lensing signal scales with redshift as expected from general relativity for a concordance ΛCDM cosmology, including the full cross-correlations between different redshift bins. Assuming a flat ΛCDM cosmology, we measure σ 8 (Ω m /0.3) 0.51 = 0.75 ± 0.08 from lensing, in perfect agreement with WMAP-5, yielding joint constraints Ω m = 0.266 +0.025 −0.023 , σ 8 = 0.802 +0.028 −0.029 (all 68.3% conf.). Dropping the assumption of flatness and using priors from the HST Key Project and Big-Bang nucleosynthesis only, we find a negative deceleration parameter q 0 at 94.3% confidence from the tomographic lensing analysis, providing independent evidence of the accelerated expansion of the Universe. For a flat wCDM cosmology and prior w ∈ [−2, 0], we obtain w < −0.41 (90% conf.). Our dark energy constraints are still relatively weak solely due to the limited area of COSMOS. However, they provide an important demonstration of the usefulness of tomographic weak lensing measurements from space.

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Section: Redshift Scaling Of Shear-shear Cross-correlationsmentioning

confidence: 88%

Evidence of the accelerated expansion of the Universe from weak lensing tomography with COSMOS

Schrabback

Hartlap

Joachimi

et al. 2010

A&A

340

454

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“…Scoville et al (2007), Mazure et al (2007), Eisenhardt et al (2008), andvan Breukelen et al (2006) have estimated the surface density in redshift slices, each with different methods: the first two use adaptive smoothing of galaxy counts, Eisenhardt et al (2008) analyse a density map convolved with a wavelet kernel, while the last author adopts FoF and Voronoi tessellation (Marinoni et al 2002). At variance with these, we preferred to adopt an adaptive 3D density estimate to consider, automatically, distances in all directions and the relevant positional accuracies at the same time.…”

Section: Comparison With Other Methods Based On Photometric Redshiftsmentioning

confidence: 99%

“…Mazure et al (2007), while Scoville et al (2007), van Breukelen et al (2006), Zatloukal et al (2007), and Eisenhardt et al (2008) consider the full probability distribution function (PDF) to take redshift uncertainties into account. As discussed by Scoville et al (2007), this last method could tend to detect structures formed by early type galaxies, since they have smaller photometric redshift uncertainty, thanks to their stronger Balmer break, when this feature is well-sampled in the observed bands. We are less biased in this respect, since we considered the photometric redshift uncertainty in a conservative way, choosing only the maximum redshift range where we count neighbour galaxies to associate with each cell.…”

Section: Comparison With Other Methods Based On Photometric Redshiftsmentioning

confidence: 99%

“…In the past few years, several authors (e.g. Botzler et al 2004;van Breukelen et al 2006;Scoville et al 2007;Zatloukal et al 2007;Mazure et al 2007;Eisenhardt et al 2008) have developed or extended known algorithms to take the greater redshift uncertainties into account. We have developed a new algorithm that uses an adaptive estimate of the 3D density field, as described in detail in Trevese et al (2007).…”

Section: Introductionmentioning

confidence: 99%

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A comprehensive study of large-scale structures in the GOODS-SOUTH field up to ${\mathsf z} \sim $ 2.5

Salimbeni

Castellano

Pentericci

et al. 2009

A&A

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Aims. The aim of the present paper is to identify and study the properties and galactic content of groups and clusters in the GOODSSouth field up to z ∼ 2.5, and to analyse the physical properties of galaxies as a continuous function of environmental density up to high redshift. Methods. We used the deep (z 850 ∼ 26), multi-wavelength GOODS-MUSIC catalogue, which has a 15% of spectroscopic redshifts and accurate photometric redshifts for the remaining fraction. On these data, we applied a (2+1)D algorithm, previously developed by our group, that provides an adaptive estimate of the 3D density field. We supported our analysis with simulations to evaluate the purity and the completeness of the cluster catalogue produced by our algorithm. Results. We find several high-density peaks embedded in larger structures in the redshift range 0.4-2.5. From the analysis of their physical properties (mass profile, M 200 , σ v , L X , U − B vs. B diagram), we find that most of them are groups of galaxies, while two are poor clusters with masses a few times 10 14 M . For these two clusters we find from the Chandra 2Ms data an X-ray emission significantly lower than expected from their optical properties, suggesting that the two clusters are either not virialised or are gas poor. We find that the slope of the colour magnitude relation, for these groups and clusters, is constant at least up to z ∼ 1. We also analyse the dependence on environment of galaxy colours, luminosities, stellar masses, ages, and star formations. We find that galaxies in high-density regions are, on average, more luminous and massive than field galaxies up to z ∼ 2. The fraction of red galaxies increases with luminosity and with density up to z ∼ 1.2. At higher z this dependence on density disappears. The variation of galaxy properties as a function of redshift and density suggests that a significant change occurs at z ∼ 1.5-2.

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“…Though scientists have so far not been able to detect dark matter particles, the information from these simulations is still valuable especially given the relationship between dark matter halos and galaxy clusters. Galaxies sit within dark matter halos and recent evidence points to filaments of dark matter forming the framework on which galaxy clusters grow [7]. A dark matter halo is a collapsed group of gravitationally bound dark matter particles.…”

Section: Introductionmentioning

confidence: 99%

Measuring Cluster Relaxedness

Moreland¹

2012

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Large Structures and Galaxy Evolution in COSMOS at z < 1.1

Cited by 167 publications

References 74 publications

Evidence of the accelerated expansion of the Universe from weak lensing tomography with COSMOS

Evidence of the accelerated expansion of the Universe from weak lensing tomography with COSMOS

A comprehensive study of large-scale structures in the GOODS-SOUTH field up to ${\mathsf z} \sim $ 2.5

Measuring Cluster Relaxedness

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