Cosmological weak lensing with the HST GEMS survey
Heymans, Catherine; Brown, Michael L.; Barden, Marco;Caldwell, John A. R.; Jahnke, Knud; Peng, Chien Y.;Rix, Hans-Walter; Taylor, Andy;Beckwith, Steven V. W.; Bell, Eric F.; Borch, Andrea;Häußler, Boris; Jogee, Shardha; McIntosh, Daniel H.;Meisenheimer, Klaus; Sánchez, Sebastian F.;Somerville, Rachel; Wisotzki, Lutz; Wolf, Christian. Cosmological weak lensing with the HST GEMS survey. Monthly Notices of the Royal Astronomical Society. 2005, Vol. Volume 361, Issue 1, pp. 160-176, p. -2005.
We present our cosmic shear analysis of GEMS, one of the largest wide-field surveys ever undertaken by the Hubble Space Telescope. Imaged with the Advanced Camera for Surveys (ACS), GEMS spans 795 arcmin2 in the Chandra Deep Field South. We detect weak lensing by large-scale structure in high-resolution F606W GEMS data from ~60 resolved galaxies per square arcminute. We measure the two-point shear correlation function, the top-hat shear variance and the shear power spectrum, performing an E/B mode decomposition for each statistic. We show that we are not limited by systematic errors and use our results to place joint constraints on the matter density parameter Ωm and the amplitude of the matter power spectrum σ8. We find σ8(Ωm/0.3)0.65= 0.68 +/- 0.13 where the 1σ error includes both our uncertainty on the median redshift of the survey and sampling variance.
Removing image and point spread function (PSF) distortions are crucial to all weak lensing analyses. We therefore include a thorough discussion on the degree of ACS PSF distortion and anisotropy which we characterize directly from GEMS data. Consecutively imaged over 20 d, GEMS data also allow us to investigate PSF instability over time. We find that, even in the relatively short GEMS observing period, the ACS PSF ellipticity varies at the level of a few per cent which we account for with a semi-time-dependent PSF model. Our correction for the temporal and spatial variability of the PSF is shown to be successful through a series of diagnostic tests.
We present our cosmic shear analysis of GEMS, one of the largest wide-field surveys ever undertaken by the Hubble Space Telescope. Imaged with the Advanced Camera for Surveys (ACS), GEMS spans 795 arcmin2 in the Chandra Deep Field South. We detect weak lensing by large-scale structure in high-resolution F606W GEMS data from ~60 resolved galaxies per square arcminute. We measure the two-point shear correlation function, the top-hat shear variance and the shear power spectrum, performing an E/B mode decomposition for each statistic. We show that we are not limited by systematic errors and use our results to place joint constraints on the matter density parameter Ωm and the amplitude of the matter power spectrum σ8. We find σ8(Ωm/0.3)0.65= 0.68 +/- 0.13 where the 1σ error includes both our uncertainty on the median redshift of the survey and sampling variance.
Removing image and point spread function (PSF) distortions are crucial to all weak lensing analyses. We therefore include a thorough discussion on the degree of ACS PSF distortion and anisotropy which we characterize directly from GEMS data. Consecutively imaged over 20 d, GEMS data also allow us to investigate PSF instability over time. We find that, even in the relatively short GEMS observing period, the ACS PSF ellipticity varies at the level of a few per cent which we account for with a semi-time-dependent PSF model. Our correction for the temporal and spatial variability of the PSF is shown to be successful through a series of diagnostic tests.