252 research outputs found
Stacked phase-space density of galaxies around massive clusters: Comparison of dynamical and lensing masses
We present a measurement of average histograms of line-of-sight velocities
over pairs of galaxies and galaxy clusters. Since the histogram can be measured
at different galaxy-cluster separations, this observable is commonly referred
to as the stacked phase-space density. We formulate the stacked phase-space
density based on a halo-model approach so that the model can be applied to real
samples of galaxies and clusters. We examine our model by using an actual
sample of massive clusters with known weak-lensing masses and spectroscopic
observations of galaxies around the clusters. A likelihood analysis with our
model enables us to infer the spherical-symmetric velocity dispersion of
observed galaxies in massive clusters. We find the velocity dispersion of
galaxies surrounding clusters with their lensing masses of to be at the 68\%
confidence level. Our constraint confirms that the relation between the galaxy
velocity dispersion and the host cluster mass in our sample is consistent with
the prediction in dark-matter-only N-body simulations under General Relativity.
Assuming that the Poisson equation in clusters can be altered by an effective
gravitational constant of , our measurement of the velocity
dispersion can place a tight constraint of at length scales of a few Mpc about Giga years ago,
where is the Newton's constant.Comment: 22 pages, 8 figures, 3 tables. Accepted for publication in MNRA
LoCuSS: Exploring the selection of faint blue background galaxies for cluster weak-lensing
Cosmological constraints from galaxy clusters rely on accurate measurements
of the mass and internal structure of clusters. An important source of
systematic uncertainty in cluster mass and structure measurements is the secure
selection of background galaxies that are gravitationally lensed by clusters.
This issue has been shown to be particular severe for faint blue galaxies. We
therefore explore the selection of faint blue background galaxies, by reference
to photometric redshift catalogs derived from the COSMOS survey and our own
observations of massive galaxy clusters at z~0.2. We show that methods relying
on photometric redshifts of galaxies in/behind clusters based on observations
through five filters, and on deep 30-band COSMOS photometric redshifts are both
inadequate to identify safely faint blue background galaxies. This is due to
the small number of filters used by the former, and absence of massive galaxy
clusters at redshifts of interest in the latter. We therefore develop a
pragmatic method to combine both sets of photometric redshifts to select a
population of blue galaxies based purely on photometric analysis. This sample
yields stacked weak-lensing results consistent with our previously published
results based on red galaxies. We also show that the stacked clustercentric
number density profile of these faint blue galaxies is consistent with
expectations from consideration of the lens magnification signal of the
clusters. Indeed, the observed number density of blue background galaxies
changes by ~10-30 per cent across the radial range over which other surveys
assume it to be flat.Comment: submitted to MNRA
PhoSim-NIRCam: Photon-by-photon image simulations of the James Webb Space Telescope's Near-Infrared Camera
Recent instrumentation projects have allocated resources to develop codes for
simulating astronomical images. Novel physics-based models are essential for
understanding telescope, instrument, and environmental systematics in
observations. A deep understanding of these systematics is especially important
in the context of weak gravitational lensing, galaxy morphology, and other
sensitive measurements. In this work, we present an adaptation of a
physics-based ab initio image simulator: The Photon Simulator (PhoSim). We
modify PhoSim for use with the Near-Infrared Camera (NIRCam) -- the primary
imaging instrument aboard the James Webb Space Telescope (JWST). This photon
Monte Carlo code replicates the observational catalog, telescope and camera
optics, detector physics, and readout modes/electronics. Importantly,
PhoSim-NIRCam simulates both geometric aberration and diffraction across the
field of view. Full field- and wavelength-dependent point spread functions are
presented. Simulated images of an extragalactic field are presented. Extensive
validation is planned during in-orbit commissioning
A high signal to noise ratio map of the Sunyaev-Zel'dovich increment at 1.1 mm wavelength in Abell 1835
We present an analysis of an 8 arcminute diameter map of the area around the
galaxy cluster Abell 1835 from jiggle map observations at a wavelength of 1.1
mm using the Bolometric Camera (Bolocam) mounted on the Caltech Submillimeter
Observatory (CSO). The data is well described by a model including an extended
Sunyaev-Zel'dovich (SZ) signal from the cluster gas plus emission from two
bright background submm galaxies magnified by the gravitational lensing of the
cluster. The best-fit values for the central Compton value for the cluster and
the fluxes of the two main point sources in the field: SMM J140104+0252, and
SMM J14009+0252 are found to be ,
6.5 mJy and 11.3 mJy, where the first error
represents the statistical measurement error and the second error represents
the estimated systematic error in the result. This measurement assumes the
presence of dust emission from the cluster's central cD galaxy of
mJy, based on higher frequency observations of Abell 1835. The cluster image
represents one of the highest-significance SZ detections of a cluster in the
positive region of the thermal SZ spectrum to date. The inferred central
intensity is compared to other SZ measurements of Abell 1835 and this
collection of results is used to obtain values for and the cluster peculiar velocity km/s.Comment: 9 pages, 5 figure
LoCuSS: The Near-Infrared Luminosity and Weak-Lensing Mass Scaling Relation of Galaxy Clusters
We present the first scaling relation between weak-lensing galaxy cluster
mass, , and near-infrared luminosity, . Our results are based on
17 clusters observed with wide-field instruments on Subaru, the United Kingdom
Infrared Telescope, the Mayall Telescope, and the MMT. We concentrate on the
relation between projected 2D weak-lensing mass and spectroscopically confirmed
luminosity within 1Mpc, modelled as , obtaining a power
law slope of and an intrinsic scatter of
. Intrinsic scatter of ~10% is a
consistent feature of our results regardless of how we modify our approach to
measuring the relationship between mass and light. For example, deprojecting
the mass and measuring both quantities within , that is itself
obtained from the lensing analysis, yields
and . We also
find that selecting members based on their (J-K) colours instead of
spectroscopic redshifts neither increases the scatter nor modifies the slope.
Overall our results indicate that near-infrared luminosity measured on scales
comparable with (typically 1Mpc for our sample) is a low scatter and
relatively inexpensive proxy for weak-lensing mass. Near-infrared luminosity
may therefore be a useful mass proxy for cluster cosmology experiments.Comment: 9 Pages, 5 Figures, 3 Tables. Submitted to MNRA
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