Cosmology

CFHTLenS tomographic weak lensing: Quantifying accurate redshift distributions

Monthly Notices of the Royal Astronomical Society 431:2 (2013) 1547-1564

Authors:

J Benjamin, L Van waerbeke, C Heymans, M Kilbinger, T Erben, H Hildebrandt, H Hoekstra, TD Kitching, Y Mellier, L Miller, B Rowe, T Schrabback, F Simpson, J Coupon, L Fu, J Harnois-déraps, MJ Hudson, K Kuijken, E Semboloni, S Vafaei, M Velander

Abstract:

The Canada-France-Hawaii Telescope Lensing Survey (CFHTLenS) comprises deep multicolour (u*g'r'i'z') photometry spanning 154 deg2, with accurate photometric redshifts and shape measurements. We demonstrate that the redshift probability distribution function summed over galaxies provides an accurate representation of the galaxy redshift distribution accounting for random and catastrophic errors for galaxies with best-fitting photometric redshifts zp < 1.3.We present cosmological constraints using tomographic weak gravitational lensing by large-scale structure. We use two broad redshift bins 0.5 < zp ≤ 0.85 and 0.85 < zp ≤ 1.3 free of intrinsic alignment contamination, and measure the shear correlation function on angular scales in the range ∼1-40 arcmin. We show that the problematic redshift scaling of the shear signal, found in previous Canada-France-Hawaii Telescope Legacy Survey data analyses, does not affect the CFHTLenS data. For a flat Λ cold dark matter model and a fixed matter density Ωm = 0.27, we find the normalization of the matter power spectrum σ8 = 0.771 ± 0.041. When combined with cosmic microwave background data (Wilkinson Microwave Anisotropy Probe 7-year results), baryon acoustic oscillation data (BOSS) and a prior on the Hubble constant from the Hubble Space Telescope distance ladder, we find that CFHTLenS improves the precision of the fully marginalized parameter estimates by an average factor of 1.5-2. Combining our results with the above cosmological probes, we find Ωm = 0.2762 ± 0.0074 and σ8 = 0.802 ± 0.013. © 2013 The Authors. Published by Oxford University Press on behalf of the Royal Astronomical Society.

CFHTlens: The environmental dependence of galaxy halo masses from weak lensing

Monthly Notices of the Royal Astronomical Society 431:2 (2013) 1439-1452

Authors:

BR Gillis, MJ Hudson, T Erben, C Heymans, H Hildebrandt, H Hoekstra, TD Kitching, Y Mellier, L Miller, L van Waerbeke, C Bonnett, J Coupon, L Fu, S Hilbert, BTP Rowe, T Schrabback, E Semboloni, E van Uitert, M Velander

Abstract:

We use weak gravitational lensing to analyse the dark matter haloes around satellite galaxies in galaxy groups in the Canada-France-Hawaii Telescope Lensing Survey (CFHTLenS) data set. This data set is derived from the Canada-France-Hawaii Telescope Legacy Survey Wide survey, and encompasses 154 deg2 of high-quality shape data. Using the photometric redshifts, we divide the sample of lens galaxies with stellar masses in the range 109-1010.5M⊙ into those likely to lie in high-density environments (HDE) and those likely to lie in low-density environments (LDE). Through comparison with galaxy catalogues extracted from the Millennium Simulation, we show that the sample of HDE galaxies should primarily (~61 per cent) consist of satellite galaxies in groups, while the sample of LDE galaxies should consist of mostly (~87 per cent) non-satellite (field and central) galaxies. Comparing the lensing signals around samples of HDE and LDE galaxies matched in stellar mass, the lensing signal around HDE galaxies clearly shows a positive contribution from their host groups on their lensing signals at radii of ~500-1000 kpc, the typical separation between satellites and group centres. More importantly, the subhaloes of HDE galaxies are less massive than those around LDE galaxies by a factor of 0.65 ± 0.12, significant at the 2.9σ level. A natural explanation is that the haloes of satellite galaxies are stripped through tidal effects in the group environment. Our results are consistent with a typical tidal truncation radius of ~40 kpc. © 2013 The Authors. Published by Oxford University Press on behalf of the Royal Astronomical Society.

Defining a weak lensing experiment in space

Monthly Notices of the Royal Astronomical Society 431:4 (2013) 3103-3126

Authors:

M Cropper, H Hoekstra, T Kitching, R Massey, J Amiaux, L Miller, Y Mellier, J Rhodes, B Rowe, S Pires, C Saxton, R Scaramella

Abstract:

This paper describes the definition of a typical next-generation space-based weak gravitational lensing experiment. We first adopt a set of top-level science requirements from the literature, based on the scale and depth of the galaxy sample, and the avoidance of systematic effects in the measurements which would bias the derived shear values. We then identify and categorize the contributing factors to the systematic effects, combining them with the correct weighting, in such a way as to fit within the top-level requirements. We present techniques which permit the performance to be evaluated and explore the limits at which the contributing factors can be managed. Besides the modelling biases resulting from the use of weighted moments, the main contributing factors are the reconstruction of the instrument point spread function, which is derived from the stellar images on the image, and the correction of the charge transfer inefficiency in the CCD detectors caused by radiation damage. © 2013 The Authors.

The "Sausage" and "Toothbrush" clusters of galaxies and the prospects of LOFAR observations of clusters of galaxies

Astronomische Nachrichten 334:4-5 (2013) 333-337

Authors:

H Röttgering, R Van Weeren, M Brüggen, J Croston, M Hoeft, G Ogrean, P Barthel, P Best, A Bonafede, G Brunetti, R Cassano, K Chyzy, J Conway, F De Gasperin, C Ferrari, G Heald, N Jackson, M Jarvis, M Lehnert, G Macario, G Miley, E Orrú, R Pizzo, D Rafferty, A Stroe, C Tasse, S Van der Tol, G White, M Wise

Abstract:

LOFAR, the Low Frequency Radio Array, is a new pan-European radio telescope that is almost fully operational. One of its main drivers is to make deep images of the low frequency radio sky. To be able to do this a number of challenges need to be addressed. These include the high data rates, removal of radio frequency interference, calibration of the beams and correcting for the corrupting influence of the ionosphere. One of the key science goals is to study merger shocks, particle acceleration mechanisms and the structure of magnetic fields in nearby and distant merging clusters. Recent studies with the GMRT and WSRT radio telescopes of the "Sausage" and the "Toothbrush" clusters have given a very good demonstration of the power of radio observations to study merging clusters. Recently we discovered that both clusters contain relic and halo sources, large diffuse regions of radio emission not associated with individual galaxies. The 2 Mpc northern relic in the Sausage cluster displays highly aligned magnetic fields and and exhibits a strong spectral index gradient that is a consequence of cooling of the synchrotron emitting particles in the post-shock region. We have argued that these observations provide strong evidence that shocks in merging clusters are capable of accelerating particles. For the Toothbrush cluster we observe a puzzling linear relic that extends over 2 Mpc. The proposed scenario is that a triplemerger can lead to such a structure. With LOFAR's sensitivity it will not only be possible to trace much weaker shocks, but also to study those shocks due to merging clusters up to redshifts of at least one. © 2013 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.

Size magnification as a complement to cosmic shear

Monthly Notices of the Royal Astronomical Society 430:4 (2013) 2844-2853

Authors:

B Casaponsa, AF Heavens, TD Kitching, L Miller, RB Barreiro, E Martínez-González

Abstract:

We investigate the extent to which cosmic size magnification may be used to complement cosmic shear in weak gravitational lensing surveys, with a view to obtaining high-precision estimates of cosmological parameters. Using simulated galaxy images, we find that unbiased estimation of the convergence field is possible using galaxies with angular sizes larger than the point spread function (PSF) and signal-to-noise ratio in excess of 10. The statistical power is similar to, but not quite as good as, cosmic shear, and it is subject to different systematic effects. Application to ground-based data will be challenging, with relatively large empirical corrections required to account for the fact that many galaxiesare smaller than the PSF, but for space-based data with 0.1-0.2 arcsec resolution, the size distribution of galaxies brighter than i≃24 is almost ideal for accurate estimation of cosmic size magnification. © 2013 The Authors. Published by Oxford University Press on behalf of the Royal Astronomical Society.