142 research outputs found
On the evolution of the entropy and pressure profiles in X-ray luminous galaxy clusters at z > 0.4
Galaxy clusters are the most recent products of hierarchical accretion over
cosmological scales. The gas accreted from the cosmic field is thermalized
inside the cluster halo. Gas entropy and pressure are expected to have a
self-similar behaviour with their radial distribution following a power law and
a generalized Navarro-Frenk-White profile, respectively. This has been shown
also in many different hydrodynamical simulations. We derive the
spatially-resolved thermodynamical properties of 47 X-ray galaxy clusters
observed with Chandra in the redshift range 0.4 < z < 1.2, the largest sample
investigated so far in this redshift range with X-rays spectroscopy, with a
particular care in reconstructing the gas entropy and pressure radial profiles.
We search for deviation from the self-similar behaviour and look for possible
evolution with redshift. The entropy and pressure profiles lie very close to
the baseline prediction from gravitational structure formation. We show that
these profiles deviate from the baseline prediction as function of redshift, in
particular at z > 0.75, where, in the central regions, we observe higher values
of the entropy (by a factor of 2.2) and systematically lower estimates (by a
factor of 2.5) of the pressure. The effective polytropic index, which retains
informations about the thermal distribution of the gas, shows a slight linear
positive evolution with the redshift and the concentration of the dark matter
distribution. A prevalence of non-cool-core, disturbed systems, as we observe
at higher redshifts, can explain such behaviours.Comment: 14 pages, 18 figures, accepted for publication by A&
Helium abundance (and ) in X-COP galaxy clusters
We present the constraints on the helium abundance in 12 X-ray luminous
galaxy clusters that have been mapped in their X-ray and Sunyaev-Zeldovich (SZ)
signals out to for the XMM-Newton Cluster Outskirts Project (X-COP).
The unprecedented precision available for the estimate of allows us to
investigate how much the reconstructed X-ray and SZ signals are consistent with
the expected ratio between helium and proton densities of 0.08-0.1. We find
that a around 70 km/s/Mpc is preferred from our measurements, with lower
values of as requested from the Planck collaboration (67 km/s/Mpc)
requiring a 34% higher value of . On the other hand, higher values of ,
as obtained by measurements in the local universe, impose , from the
primordial nucleosynthesis calculations and current solar abundances, reduced
by 37--44\%.Comment: 7 pages. To appear as proceedings article for the XMM-Newton Workshop
"Astrophysics of Hot Plasma in Extended X-ray Sources" held at European Space
Astronomy Centre, Madrid, Spain, on 12-14 June 201
Polytropic state of the intracluster medium in the X-COP cluster sample
Aims: In this work, we have investigated the relation between the radially resolved thermodynamic quantities of the intracluster medium in the X-COP cluster sample, aiming to assess the stratification properties of the ICM. Methods: We modeled the relations between radius, gas temperature, density, and pressure using a combination of power-laws, also evaluating the intrinsic scatter in these relations. Results: We show that the gas pressure is remarkably well correlated to the density, with very small scatter. Also the temperature correlates with gas density with similar scatter. The slopes of these relations have values that show a clear transition from the inner cluster regions to the outskirts. This transition occurs at the radius rt = 0.19(±0.04) R500 and electron density nt = (1.91 ± 0.21) à 10-3 cm-3 E2(z). We find that above 0.2 R500 the radial thermodynamic profiles are accurately reproduced by a well defined and physically motivated framework, where the dark matter follows the NFW potential and the gas is represented by a polytropic equation of state. By modeling the gas temperature dependence upon both the gas density and radius, we propose a new method to reconstruct the hydrostatic mass profile based only on the relatively inexpensive measurement of the gas density profile
The XMM Cluster Outskirts Project (X-COP): thermodynamic properties of the intracluster medium out to R 200 in Abell 2319
Aims. We present the joint analysis of the X-ray and Sunyaev Zelâdovich(SZ) signals in Abell 2319, the galaxy cluster with the highest signal-to-noise ratio in SZ Planck maps and that has been surveyed within our XMM-Newton Cluster Outskirts Project (X-COP), a very large program which aims to grasp the physical condition in 12 local (z < 0.1) and massive (M200 > 3 Ă 1014 Mâ) galaxy clusters out to R200 and beyond.
Methods. We recover the profiles of the thermodynamic properties by the geometrical deprojection of the X-ray surface brightness, of the SZ Comptonization parameter, and accurate and robust spectroscopic measurements of the gas temperature out to 3.2 Mpc (1.6 R200 ), 4 Mpc (2 R200 ), and 1.6 Mpc (0.8 R200 ), respectively. We resolve the clumpiness of the gas density to be below 20% over the entire observed volume. We also demonstrate that most of this clumpiness originates from the ongoing merger and can be associated with large-scale inhomogeneities (the âresidualâ clumpiness). We estimate the total mass through the hydrostatic equilibrium equation. This analysis is done both in azimuthally averaged radial bins and in eight independent angular sectors, enabling us to study in detail the azimuthal variance of the recovered properties.
Results. Given the exquisite quality of the X-ray and SZ datasets, their radial extension, and their complementarity, we constrain at R200 the total hydrostatic mass, modelled with a NavarroâFrenkâWhite profile at very high precision (M200 = 10.7 ± 0.5stat. ± 0.9syst. Ă 1014 Mâ). We identify the ongoing merger and how it is affecting differently the gas properties in the resolved azimuthal sectors. We have several indications that the merger has injected a high level of non-thermal pressure in this system: the clumping free density profile is above the average profile obtained by stacking Rosat/PSPC observations; the gas mass fraction recovered using our hydrostatic mass profile exceeds the expected cosmic gas fraction beyond R500; the pressure profile is flatter than the fit obtained by the Planck Collaboration; the entropy profile is flatter than the mean profile predicted from non-radiative simulations; the analysis in azimuthal sectors has revealed that these deviations occur in a preferred region of the cluster. All these tensions are resolved by requiring a relative support of about 40% from non-thermal to the total pressure at R200
Effects of Multiphase Gas and Projection on X-ray Observables in Simulated Galaxy Clusters as Seen by eROSITA
The number density of galaxy clusters as a function of mass and redshift is a
sensitive function of the cosmological parameters. To use clusters for
cosmological parameter studies, it is necessary to determine their masses as
accurately as possible, which is typically done via mass-observable scaling
relations. X-ray observables can be biased by multiphase gas and projection
effects, especially in the case where cluster temperatures and luminosities are
estimated from single-model fits to all of the emission with a given radius.
Using simulated galaxy clusters from a realistic cosmological simulation, we
seek to determine the importance of these biases in the context of
Spectrum-Roentgen-Gamma/eROSITA observations of clusters. We extract clusters
from the Magneticum suite, and simulate eROSITA observations of these clusters
using PHOX and SIXTE. We compare the fitted observables from these observations
to those derived from the simulations. We fitted an intrinsically scattered
scaling relation to these measurements following a Bayesian
approach with which we fully took into account the selection effects and the
mass function. The largest biases on the cluster observables come from the
inadequacy of single-temperature model fits to represent emission from
multiphase gas, as well as a bias arising from cluster emission within the
projected along the line of sight but outside of the spherical
. We find that the biases on temperature and luminosity due to the
projection of emission from other clusters within is small. We find
that our simulated clusters follow a scaling relation that has a
broadly consistent but slightly shallower slope compared to the literature, and
that the intrinsic scatter of at given T is lower compared to the
recent observational results where the selection effects are fully considered.Comment: 18 pages, 17 figures, accepted by A&
Iron in x-cop: Tracing enrichment in cluster outskirts with high accuracy abundance profiles
We present the first metal abundance profiles for a representative sample of massive clusters. Our measurements extend to R500 and are corrected for a systematic error plaguing previous outskirt estimates. Our profiles flatten out at large radii, admittedly not a new result, however the radial range and representative nature of our sample extends its import well beyond previous findings. We find no evidence of segregation between cool-core and non-cool-core systems beyond 3c0.3\ue2 R500, implying that, as was found for thermodynamic properties, the physical state of the core does not affect global cluster properties. Our mean abundance within R500 shows a very modest scatter, < 15%, suggesting the enrichment process must be quite similar in all these massive systems. This is a new finding and has significant implications for feedback processes. Together with results from the thermodynamic properties presented in a previous X-COP paper, it affords a coherent picture in which feedback effects do not vary significantly from one system to another. By combining intra-cluster medium with stellar measurements we have found the amount of Fe diffused in the intra-cluster medium to be about ten times higher than that locked in stars. Although our estimates suggest, with some strength, that the measured iron mass in clusters is well in excess of the predicted one, systematic errors prevent us from making a definitive statement. Further advancements will only be possible when systematic uncertainties, principally those associated with stellar masses, both within and beyond R500, can be reduced
Non-thermal pressure support in X-COP galaxy clusters
Galaxy clusters are the endpoints of structure formation and are continuously growing through the merging and accretion of smaller structures. Numerical simulations predict that a fraction of their energy content is not yet thermalized, mainly in the form of kinetic motions (turbulence, bulk motions). Measuring the level of non-thermal pressure support is necessary to understand the processes leading to the virialization of the gas within the potential well of the main halo and to calibrate the biases in hydrostatic mass estimates. We present high-quality measurements of hydrostatic masses and intracluster gas fraction out to the virial radius for a sample of 13 nearby clusters with available XMM-Newton and Planck data. We compare our hydrostatic gas fractions with the expected universal gas fraction to constrain the level of non-thermal pressure support. We find that hydrostatic masses require little correction and infer a median non-thermal pressure fraction of âŒ6% and âŒ10% at R500 and R200, respectively. Our values are lower than the expectations of hydrodynamical simulations, possibly implying a faster thermalization of the gas. If instead we use the mass calibration adopted by the Planck team, we find that the gas fraction of massive local systems implies a mass bias 1 â b = 0.85 ± 0.05 for Sunyaevâ Zeldovich-derived masses, with some evidence for a mass-dependent bias. Conversely, the high bias required to match Planck cosmic microwave background and cluster count cosmology is excluded by the data at high significance, unless the most massive halos are missing a substantial fraction of their baryons
The distribution of dark matter and gas spanning six megaparsecs around the post-merger galaxy cluster MS0451-03
Using the largest mosaic of Hubble Space Telescope images around a galaxy cluster, we map the distribution of dark matter throughout an âŒ6 Ă 6âMpc2 area centred on the cluster MSâ0451â03 (z = 0.54, M200=1.65Ă1015Mââ ). Our joint strong- and weak-lensing analysis shows three possible filaments extending from the cluster, encompassing six group-scale substructures. The dark matter distribution in the cluster core is elongated, consists of two distinct components, and is characterized by a concentration parameter of c200 = 3.79 ± 0.36. By contrast, XMMâNewton observations show the gas distribution to be more spherical, with excess entropy near the core, and a lower concentration of c200=2.35+0.89â0.70 (assuming hydrostatic equilibrium). Such a configuration is predicted in simulations of major mergers 2â7âGyr after the first core passage, when the two dark matter haloes approach second turnaround, and before their gas has relaxed. This post-merger scenario finds further support in optical spectroscopy of the clusterâs member galaxies, which shows that star formation was abruptly quenched 5âGyr ago. MSâ0451â03 will be an ideal target for future studies of the growth of structure along filaments, star formation processes after a major merger, and the late-stage evolution of cluster collisions
X-ray analysis of JWST's first galaxy cluster lens SMACS J0723.3-7327
SMACS~J0723.3-7327 is the first galaxy cluster lens observed by JWST. Based
on the ERO data from JWST, several groups have reported the results on strong
lensing analysis and mass distribution of this cluster. However, limited by the
angular coverage of the JWST data, the strong lensing models only cover the
central region. X-ray analysis on the hot ICM is necessary to obtain a more
complete constraint on the mass distribution in this very massive cluster. In
this work, we aim to perform a comprehensive X-ray analysis of J0723 to obtain
accurate ICM hydrostatic mass measurements, using the X-ray data from
SRG/eROSITA and Chandra X-ray observatories. By comparing the hydrostatic mass
profile with the strong lensing model, we aim to provide the most reliable
constraint on the distribution of mass up to R500. Thanks to the eROSITA
all-sky survey and Chandra data, which provide high S/N and high angular
resolution respectively, we are able to constrain the ICM gas density profile
and temperature profile with good accuracy both in the core and to the
outskirts. With the density and temperature profiles, we compute the
hydrostatic mass profile, which is then projected along the line of sight to
compare with the mass distribution obtained from the recent strong lensing
analysis based on JWST data. We also deproject the strong lensing mass
distribution using the hydrostatic mass profile we obtained in this work. The
X-ray results obtained from eROSITA and Chandra agree very well with each
other. The hydrostatic mass profiles we measured in this work, both projected
and deprojected, are in good agreement with recent strong lensing results based
on JWST data, at all radii. We also find that the radial acceleration relation
in J0723 is inconsistent with the RAR for spiral galaxies, implying that the
latter is not a universal property of gravity across all mass scales.Comment: Accepted for publication in A&
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