391 research outputs found
Complex Physics in Cluster Cores: Showstopper for the Use of Clusters for Cosmology?
The influence of cool galaxy cluster cores on the X-ray
luminosity--gravitational mass relation is studied with Chandra observations of
64 clusters in the HIFLUGCS sample. As preliminary results we find (i) a
significant offset of cool core (CC) clusters to the high luminosity (or low
mass) side compared to non-cool core (NCC) clusters, (ii) a smaller scatter of
CC clusters compared to NCC clusters, (iii) a decreasing fraction of CC
clusters with increasing cluster mass, (iv) a reduced scatter in the
luminosity--mass relation for the entire sample if the luminosity is scaled
properly with the central entropy. The implications of these results on the
intrinsic scatter are discussed.Comment: 6 pages; to appear in the proceedings of the conference Heating vs.
Cooling in Galaxies and Clusters of Galaxies, edited by H. Boehringer, P.
Schuecker, G.W. Pratt, and A. Finoguenov. Dedicated to the memory of Peter
Schuecke
Investigating the cores of fossil systems with Chandra
We investigate the cores of fossil galaxy groups and clusters (`fossil
systems') using archival Chandra data for a sample of 17 fossil systems. We
determined the cool-core fraction for fossils via three observable diagnostics,
the central cooling time, cuspiness, and concentration parameter. We quantified
the dynamical state of the fossils by the X-ray peak/brightest cluster galaxy
(BCG), and the X-ray peak/emission weighted centre separations. We studied the
X-ray emission coincident with the BCG to detect the presence of potential
thermal coronae. A deprojection analysis was performed for z < 0.05 fossils to
obtain cooling time and entropy profiles, and to resolve subtle temperature
structures. We investigated the Lx-T relation for fossils from the 400d
catalogue to see if the scaling relation deviates from that of other groups.
Most fossils are identified as cool-core objects via at least two cool-core
diagnostics. All fossils have their dominant elliptical galaxy within 50 kpc of
the X-ray peak, and most also have the emission weighted centre within that
distance. We do not see clear indications of a X-ray corona associated with the
BCG unlike that has been observed for some other objects. Fossils do not have
universal temperature profiles, with some low-temperature objects lacking
features that are expected for ostensibly relaxed objects with a cool-core. The
entropy profiles of the z < 0.05 fossil systems can be well-described by a
power law model, albeit with indices smaller than 1. The 400d fossils Lx-T
relation shows indications of an elevated normalisation with respect to other
groups, which seems to persist even after factoring in selection effects.Comment: Accepted for publication in Astronomy and Astrophysic
Scaling relations for galaxy clusters: properties and evolution
Well-calibrated scaling relations between the observable properties and the
total masses of clusters of galaxies are important for understanding the
physical processes that give rise to these relations. They are also a critical
ingredient for studies that aim to constrain cosmological parameters using
galaxy clusters. For this reason much effort has been spent during the last
decade to better understand and interpret relations of the properties of the
intra-cluster medium. Improved X-ray data have expanded the mass range down to
galaxy groups, whereas SZ surveys have openened a new observational window on
the intracluster medium. In addition,continued progress in the performance of
cosmological simulations has allowed a better understanding of the physical
processes and selection effects affecting the observed scaling relations. Here
we review the recent literature on various scaling relations, focussing on the
latest observational measurements and the progress in our understanding of the
deviations from self similarity.Comment: 38 pages. Review paper. Accepted for publication in Space Science
Reviews (eds: S. Ettori, M. Meneghetti). This is a product of the work done
by an international team at the International Space Science Institute (ISSI)
in Bern on "Astrophysics and Cosmology with Galaxy Clusters: the X-ray and
Lensing View
Studying the Nature of Dark Energy with Galaxy Clusters
We report on the status of our effort to constrain the nature of dark energy
through the evolution of the cluster mass function. Chandra temperature
profiles for 31 clusters from a local cluster sample are shown. The X-ray
appearance of the proto supermassive binary black hole at the center of the
cluster Abell 400 is described. Preliminary weak lensing results obtained with
Megacam@MMT for a redshift z=0.5 cluster from a distant cluster sample are
given.Comment: 5 pages, to appear in: Aschenbach, B., Burwitz, V., Hasinger, G.,
Leibundgut, B. (eds.), Relativistic Astrophysics and Cosmology - Einstein's
Legacy. ESO Astrophysics Symposia, Springer Verlag, Berlin, German
X-ray Substructure Studies of Four Galaxy Clusters using XMM-Newton Data
Mahdavi et al. find that the degree of agreement between weak lensing and
X-ray mass measurements is a function of cluster radius. Numerical simulations
also point out that X-ray mass proxies do not work equally well at all radii.
The origin of the effect is thought to be associated with cluster mergers.
Recent work presenting the cluster maps showed an ability of X-ray maps to
reveal and study cluster mergers in detail. Here we present a first attempt to
use the study of substructure in assessing the systematics of the hydrostatic
mass measurements using two-dimensional (2-D) X-ray diagnostics. The
temperature map is uniquely able to identify the substructure in an almost
relaxed cluster which would be unnoticed in the ICM electron number density and
pressure maps. We describe the radial fluctuations in the 2-D maps by a
cumulative/differential scatter profile relative to the mean profile within/at
a given radius. The amplitude indicates ~10 fluctuations in the temperature,
electron number density and entropy maps, and ~15 fluctuations in the pressure
map. The amplitude of and the discontinuity in the scatter complement 2-D
substructure diagnostics, e.g. indicating the most disturbed radial range.
There is a tantalizing link between the substructure identified using the
scatter of the entropy and pressure fluctuations and the hydrostatic mass bias
relative to the expected mass based on the M-Yx and M-Mgas relations
particularly at r500. XMM-Newton observations with ~120,000 source photons from
the cluster are sufficient to apply our substructure diagnostics via the
spectrally measured 2-D temperature, electron number density, entropy and
pressure maps.Comment: 44 pages, 16 figures, 3 tables, including some language editing from
ApJ, published in Ap
The Cool-Core Bias in X-ray Galaxy Cluster Samples I: Method And Application To HIFLUGCS
When selecting flux-limited cluster samples, the detection efficiency of
X-ray instruments is not the same for centrally-peaked and flat objects, which
introduces a bias in flux-limited cluster samples. We quantify this effect in
the case of a well-known cluster sample, HIFLUGCS. We simulate a population of
X-ray clusters with various surface-brightness profiles, and use the
instrumental characteristics of the ROSAT All-Sky Survey (RASS) to select
flux-limited samples similar to the HIFLUGCS sample and predict the expected
bias. For comparison, we also estimate observationally the bias in the HIFLUGCS
sample using XMM-Newton and ROSAT data. We find that the selection of X-ray
cluster samples is significantly biased () in favor of the peaked,
Cool-Core (CC) objects, with respect to Non-Cool-Core (NCC) systems.
Interestingly, we find that the bias affects the low-mass, nearby objects
(groups, poor clusters) much more than the more luminous objects (i.e massive
clusters). We also note a moderate increase of the bias for the more distant
systems. Observationally, we propose to select the objects according to their
flux in a well-defined physical range excluding the cores,
, to get rid of the bias. From the fluxes in this range, we
reject 13 clusters out of the 64 in the HIFLUGCS sample, none of which appears
to be NCC. As a result, we estimate that less than half (35-37%) of the galaxy
clusters in the local Universe are strong CC. In the paradigm where the CC
objects trace relaxed clusters as opposed to unrelaxed, merging objects, this
implies that to the present day the majority of the objects are not in a
relaxed state. From this result, we estimate a rate of heating events of
Gyr per dark-matter halo.Comment: 16 pages, 9 figures, accepted for publication in A&
Virial mass in DGP brane cosmology
We study the virial mass discrepancy in the context of a DPG brane-world
scenario and show that such a framework can offer viable explanations to
account for the mass discrepancy problem. This is done by defining a
geometrical mass that we prove to be proportional to the virial
mass. Estimating using observational data, we show that it
behaves linearly with and has a value of the order of , pointing
to a possible resolution of the virial mass discrepancy. We also obtain the
radial velocity dispersion of galaxy clusters and show that it is compatible
with the radial velocity dispersion profile of such clusters. This velocity
dispersion profile can be used to differentiate various models predicting the
virial mass.Comment: 12 pages, 1 figure, to appear in CQ
- …