144 research outputs found
A magnified glance into the dark sector: probing cosmological models with strong lensing in A1689
In this paper we constrain four alternative models to the late cosmic
acceleration in the Universe: Chevallier-Polarski-Linder (CPL), interacting
dark energy (IDE), Ricci holographic dark energy (HDE), and modified polytropic
Cardassian (MPC). Strong lensing (SL) images of background galaxies produced by
the galaxy cluster Abell are used to test these models. To perform this
analysis we modify the LENSTOOL lens modeling code. The value added by this
probe is compared with other complementary probes: Type Ia supernovae (SNIa),
baryon acoustic oscillations (BAO), and cosmic microwave background (CMB). We
found that the CPL constraints obtained of the SL data are consistent with
those estimated using the other probes. The IDE constraints are consistent with
the complementary bounds only if large errors in the SL measurements are
considered. The Ricci HDE and MPC constraints are weak but they are similar to
the BAO, SNIa and CMB estimations. We also compute the figure-of-merit as a
tool to quantify the goodness of fit of the data. Our results suggest that the
SL method provides statistically significant constraints on the CPL parameters
but weak for those of the other models. Finally, we show that the use of the SL
measurements in galaxy clusters is a promising and powerful technique to
constrain cosmological models. The advantage of this method is that
cosmological parameters are estimated by modelling the SL features for each
underlying cosmology. These estimations could be further improved by SL
constraints coming from other galaxy clusters.Comment: 13 pages, 5 figures, accepted for publication in Ap
Source plane reconstruction of the giant gravitational arc in Abell 2667: a candidate Wolf-Rayet galaxy at z~1
We present a new analysis of HST, Spitzer telescope imaging and VLT imaging
and spectroscopic data of a bright lensed galaxy at =1.0334 in the lensing
cluster Abell~2667. Using this high-resolution imaging we present an updated
lens model that allows us to fully understand the lensing geometry and
reconstruct the lensed galaxy in the source plane. This giant arc gives a
unique opportunity to peer into the structure of a high-redshift disk galaxy.
We find that the lensed galaxy of Abell 2667 is a typical spiral galaxy with
morphology similar to the structure of its counterparts at higher redshift
. The surface brightness of the reconstructed source galaxy in the
z band reveals the central surface brightness mag
arcsec and the characteristic radius kpc at redshift
. The morphological reconstruction in different bands shows obvious
negative radial color gradients for this galaxy. Moreover, the redder central
bulge tends to contain a metal-rich stellar population, rather than being
heavily reddened by dust due to high and patchy obscuration. We analyze the
VIMOS/IFU spectroscopic data and find that, in the given wavelength range
( \AA), the combined arc spectrum of the source galaxy is
characterized by a strong continuum emission with strong UV absorption lines
(FeII and MgII) and shows the features of a typical starburst Wolf-Rayet galaxy
NGC5253. More specifically, we have measured the EWs of FeII and MgII lines in
the Abell 2667 spectrum, and obtained similar values for the same wavelength
interval of the NGC5253 spectrum. Marginal evidence for CIII] 1909 emission at
the edge of the grism range further confirms our expectation.Comment: 20 pages, 7 figures, 1 table, accepted by the Astronomical Journa
The Density Profiles of Massive, Relaxed Galaxy Clusters. I. The Total Density Over Three Decades in Radius
Clusters of galaxies are excellent locations to probe the distribution of
baryons and dark matter (DM) over a wide range of scales. We study a sample of
seven massive, relaxed galaxy clusters with centrally-located brightest cluster
galaxies (BCGs) at z=0.2-0.3. Using the observational tools of strong and weak
gravitational lensing, combined with resolved stellar kinematics within the
BCG, we measure the total radial density profile, comprising both dark and
baryonic matter, over scales of ~3-3000 kpc. Lensing-derived mass profiles
typically agree with independent X-ray estimates within ~15%, suggesting that
departures from hydrostatic equilibrium are small and that the clusters in our
sample (except A383) are not strongly elongated along the line of sight. The
inner logarithmic slope gamma_tot of the total density profile measured over
r/r200=0.003-0.03, where rho_tot ~ r^(-gamma_tot), is found to be nearly
universal, with a mean = 1.16 +- 0.05 (random) +0.05-0.07
(systematic) and an intrinsic scatter of < 0.13 (68% confidence). This is
further supported by the very homogeneous shape of the observed velocity
dispersion profiles, obtained via Keck spectroscopy, which are mutually
consistent after a simple scaling. Remarkably, this slope agrees closely with
numerical simulations that contain only dark matter, despite the significant
contribution of stellar mass on the scales we probe. The Navarro-Frenk-White
profile characteristic of collisionless cold dark matter is a better
description of the total mass density at radii >~ 5-10 kpc than that of dark
matter alone. Hydrodynamical simulations that include baryons, cooling, and
feedback currently provide a poorer match. We discuss the significance of our
findings for understanding the assembly of BCGs and cluster cores, particularly
the influence of baryons on the inner DM halo. [abridged]Comment: Updated to matched the published version in Ap
Weak lensing analysis of CODEX clusters using dark energy camera legacy survey : mass-richness relation
We present the weak-lensing analysis of 279 CODEX clusters using imaging data from 4200 deg(2) of the DECam Legacy Survey (DECaLS) Data Release 3. The cluster sample results from a joint selection in X-ray, optical richness in the range 20 proportional to M-0 (lambda/40)(F lambda). By measuring the CODEX cluster sample as an individual cluster, we obtain the best-fitting values, M-0 = 3.24(-0.27)(+0.29) x 10(14)M(circle dot), and F-lambda = 1.00(-0.22)(+0.22) for the richness scaling index, consistent with a power-law relation. Moreover, we separate the cluster sample into three richness groups; lambda = 20-30, 30-50, and 50-110, and measure the stacked excess surface mass density profile in each group. The results show that both methods are consistent. In addition, we find an excellent agreement between our weak lensing based scaling relation and the relation obtained with dynamical masses estimated from cluster member velocity dispersions measured by the SDSS-IV/SPIDERS team. This suggests that the cluster dynamical equilibrium assumption involved in the dynamical mass estimates is statistically robust for a large sample of clusters.Peer reviewe
The behaviour of dark matter associated with 4 bright cluster galaxies in the 10kpc core of Abell 3827
Galaxy cluster Abell 3827 hosts the stellar remnants of four almost equally
bright elliptical galaxies within a core of radius 10kpc. Such corrugation of
the stellar distribution is very rare, and suggests recent formation by several
simultaneous mergers. We map the distribution of associated dark matter, using
new Hubble Space Telescope imaging and VLT/MUSE integral field spectroscopy of
a gravitationally lensed system threaded through the cluster core. We find that
each of the central galaxies retains a dark matter halo, but that (at least)
one of these is spatially offset from its stars. The best-constrained offset is
1.62+/-0.48kpc, where the 68% confidence limit includes both statistical error
and systematic biases in mass modelling. Such offsets are not seen in field
galaxies, but are predicted during the long infall to a cluster, if dark matter
self-interactions generate an extra drag force. With such a small physical
separation, it is difficult to definitively rule out astrophysical effects
operating exclusively in dense cluster core environments - but if interpreted
solely as evidence for self-interacting dark matter, this offset implies a
cross-section sigma/m=(1.7+/-0.7)x10^{-4}cm^2/g x (t/10^9yrs)^{-2}, where t is
the infall duration.Comment: 15 pages, 9 figure
Stellar-to-halo mass relation of cluster galaxies
In the hierarchical formation model, galaxy clusters grow by accretion of
smaller groups or isolated galaxies. During the infall into the centre of a
cluster, the properties of accreted galaxies change. In particular, both
observations and numerical simulations suggest that its dark matter halo is
stripped by the tidal forces of the host.
We use galaxy-galaxy weak lensing to measure the average mass of dark matter
haloes of satellite galaxies as a function of projected distance to the centre
of the host, for different stellar mass bins. Assuming that the stellar
component of the galaxy is less disrupted by tidal stripping, stellar mass can
be used as a proxy of the infall mass. We study the stellar to halo mass
relation of satellites as a function of the cluster-centric distance to measure
tidal stripping.
We use the shear catalogues of the DES science verification archive, the
CFHTLenS and the CFHT Stripe 82 (CS82) surveys, and we select satellites from
the redMaPPer catalogue of clusters. For galaxies located in the outskirts of
clusters, we find a stellar to halo mass relation in good agreement with the
theoretical expectations from \citet{moster2013} for central galaxies. In the
centre of the cluster, we find that this relation is shifted to smaller halo
mass for a given stellar mass. We interpret this finding as further evidence
for tidal stripping of dark matter haloes in high density environments.Comment: 15 pages, 14 figure
Stochastic bias of colour-selected BAO tracers by joint clustering-weak lensing analysis
The baryon acoustic oscillation (BAO) feature in the two-point correlation
function of galaxies supplies a standard ruler to probe the expansion history
of the Universe. We study here several galaxy selection schemes, aiming at
building an emission-line galaxy (ELG) sample in the redshift range
, that would be suitable for future BAO studies, providing a highly
biased galaxy sample. We analyse the angular galaxy clustering of galaxy
selections at the redshifts 0.5, 0.7, 0.8, 1 and 1.2 and we combine this
analysis with a halo occupation distribution (HOD) model to derive the
properties of the haloes these galaxies inhabit, in particular the galaxy bias
on large scales. We also perform a weak lensing analysis (aperture statistics)
to extract the galaxy bias and the cross-correlation coefficient and compare to
the HOD prediction.
We apply this analysis on a data set composed of the photometry of the deep
co-addition on Sloan Digital Sky Survey (SDSS) Stripe 82 (225 deg), of
Canda-France-Hawai Telescope/Stripe 82 deep \emph{i}-band weak lensing survey
and of the {\it Wide-Field Infrared Survey Explorer}infrared photometric band
W1.
The analysis on the SDSS-III/constant mass galaxies selection at is
in agreement with previous studies on the tracer, moreover we measure its
cross-correlation coefficient . For the higher redshift bins, we
confirm the trends that the brightest galaxy populations selected are strongly
biased (), but we are limited by current data sets depth to derive
precise values of the galaxy bias. A survey using such tracers of the mass
field will guarantee a high significance detection of the BAO.Comment: 17 pages, 15 figures, submitted to MNRA
LCDM halo substructure properties revealed with high resolution and large volume cosmological simulations
We investigate the structural properties, distribution and abundance of LCDM
dark matter subhaloes using the Phi-4096 and Uchuu suite of N-body cosmological
simulations. Thanks to the combination of their large volume, high mass
resolution and superb statistics, we are able to quantify -- for the first time
consistently over more than seven decades in ratio of subhalo-to-host-halo mass
-- dependencies of subhalo properties with mass, maximum circular velocity,
Vmax, host halo mass and distance to host halo centre. We also dissect the
evolution of these dependencies over cosmic time. We provide accurate fits for
the subhalo mass and velocity functions, both exhibiting decreasing power-law
slopes in the expected range of values and with no significant dependence on
redshift. We also find subhalo abundance to depend weakly on host halo mass. We
explore the distribution of subhaloes within their hosts and its evolution over
cosmic time for subhaloes located as deep as ~0.1 per cent of the host virial
radius. Subhalo structural properties are codified via a concentration
parameter, cV, that does not depend on any specific, pre-defined density
profile and relies only on Vmax. We derive the cV-Vmax relation in the range
7-1500 km/s and find an important dependence on distance of the subhalo to the
host halo centre, as already described in Molin\'e et al. (2017).
Interestingly, we also find subhaloes of the same mass to be significantly more
concentrated into more massive hosts. Finally, we investigate the redshift
evolution of cV, and provide accurate fits that take into account all mentioned
dependencies. Our results offer an unprecedented detailed characterization of
the subhalo population, consistent over a wide range of subhalo and host halo
masses, as well as cosmic times. Our work enables precision work in any future
research involving dark matter halo substructure.Comment: 17 pages, 15 figures, 5 tables. Submitted to the journal. Comments
welcome
DESI-253.2534+26.8843: A New Einstein Cross Spectroscopically Confirmed with VLT/MUSE and Modeled with GIGA-Lens
Gravitational lensing provides unique insights into astrophysics and
cosmology, including the determination of galaxy mass profiles and constraining
cosmological parameters. We present spectroscopic confirmation and lens
modeling of the strong lensing system DESI-253.2534+26.8843, discovered in the
Dark Energy Spectroscopic Instrument (DESI) Legacy Imaging Surveys data. This
system consists of a massive elliptical galaxy surrounded by four blue images
forming an Einstein Cross pattern. We obtained spectroscopic observations of
this system using the Multi Unit Spectroscopic Explorer (MUSE) on ESO's Very
Large Telescope (VLT) and confirmed its lensing nature. The main lens, which is
the elliptical galaxy, has a redshift of , while the
spectra of the background source images are typical of a starburst galaxy and
have a redshift of . Additionally, we identified a faint
galaxy foreground of one of the lensed images, with a redshift of . We employed the GIGA-Lens modeling code to characterize this system and
determined the Einstein radius of the main lens to be , which corresponds to a velocity dispersion of
= 379 2 km s. Our study contributes to a growing catalog
of this rare kind of strong lensing systems and demonstrates the effectiveness
of spectroscopic integral field unit observations and advanced modeling
techniques in understanding the properties of these systems.Comment: Accepted for publication in ApJ
Weak lensing mass map and peak statistics in Canada-France-Hawaii Telescope Stripe 82 survey
We present a weak lensing mass map covering ~124 square degrees of the
Canada-France-Hawaii Telescope Stripe 82 Survey (CS82). We study the statistics
of rare peaks in the map, including peak abundance, the peak-peak correlation
functions and the tangential-shear profiles around peaks. We find that the
abundance of peaks detected in CS82 is consistent with predictions from a
Lambda-CDM cosmological model, once noise effects are properly included. The
correlation functions of peaks with different signal-to-noise ratio (SNR) are
well described by power laws, and there is a clear cross-correlation between
the Sloan Digital Sky Survey III/Constant Mass galaxies and high SNR peaks. The
tangential-shear profiles around peaks increase with peak SNR. We fit
analytical models to the tangential-shear profiles, including a projected
singular isothermal sphere (SIS) model and a projected Navarro, Frenk & White
(NFW) model, plus a two-halo term. For the high SNR peaks, the SIS model is
rejected at ~3-sigma. The NFW model plus a two-halo term gives more acceptable
fits to the data. Some peaks match the positions of optically detected
clusters, while others are relatively dark. Comparing dark and matched peaks,
we find a difference in lensing signal of a factor of 2, suggesting that about
half of the dark peaks are false detections.Comment: 10 pages, 12 figures, Published in MNRA
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