232,709 research outputs found
AGN and Cooling Flows
For two decades the steady-state cooling-flow model has dominated the
literature of cluster and elliptical-galaxy X-ray sources. For ten years this
model has been in severe difficulty from a theoretical point of view, and it is
now coming under increasing pressure observationally. For two decades the
steady-state cooling-flow model has dominated the literature of cluster and
elliptical-galaxy X-ray sources. For ten years this model has been in severe
difficulty from a theoretical point of view, and it is now coming under
increasing pressure observationally. A small number of enthusiasts have argued
for a radically different interpretation of the data, but had little impact on
prevailing opinion because the unsteady heating picture that they advocate is
extremely hard to work out in detail. Here I explain why it is difficult to
extract robust observational predictions from the heating picture. Major
problems include the variability of the sources, the different ways in which a
bi-polar flow can impact on X-ray emission, the weakness of synchrotron
emission from sub-relativistic flows, and the sensitivity of synchrotron
emission to a magnetic field that is probably highly localized.Comment: 6 pages to appear in Particles and Fields in Radio Galaxies, eds R.A.
Laing and K.M. Blundell, ASP Conf Se
Conduction and cooling flows
Chandra and XMM-Newton observations have confirmed the presence of large
temperature gradients within the cores of many relaxed clusters of galaxies.
Here we investigate whether thermal conduction operating over those gradients
can supply sufficient heat to offset radiative cooling. Narayan & Medvedev
(2001) and Gruzinov (2002) have noted, using published results on cluster
temperatures, that conduction within a factor of a few of the Spitzer rate is
sufficient to balance bremsstrahlung cooling. From a detailed study of the
temperature and emission measure profiles of Abell 2199 and Abell 1835, we find
that the heat flux required by conduction is consistent with or below the rate
predicted by Spitzer in the outer regions of the core. Conduction may therefore
explain the lack of observational evidence for large mass cooling rates
inferred from arguments based simply on radiative cooling, provided that
conductivity is suppressed by no more than a factor of three below the full
Spitzer rate. To stem cooling in the cluster centre, however, would necessitate
conductivity values at least a factor of two larger than the Spitzer values,
which we consider implausible. This may provide an explanation for the observed
star formation and optical nebulosities in cluster cores. The solution is
likely to be time dependent. We briefly discuss the possible origin of the
cooler gas and the implications for massive galaxies.Comment: 5 pages, 4 figures, accepted by MNRAS. Minor changes following
referee's comment
ASCA and ROSAT observations of nearby cluster cooling flows
We present a detailed analysis of the X-ray properties of the cooling flows
in a sample of nearby, X-ray bright clusters of galaxies using high-quality
ASCA spectra and ROSAT X-ray images. We demonstrate the need for multiphase
models to consistently explain the spectral and imaging X-ray data for the
clusters. The mass deposition rates of the cooling flows, independently
determined from the ASCA spectra and ROSAT images, exhibit reasonable
agreement. We confirm the presence of intrinsic X-ray absorption in the
clusters using a variety of spectral models. We also report detections of
extended m infrared emission, spatially coincident with the cooling
flows, in several of the systems studied. The observed infrared fluxes and flux
limits are in good agreement with the predicted values due to reprocessed X-ray
emission from the cooling flows. We present precise measurements of the
abundances of iron, magnesium, silicon and sulphur in the central regions of
the Virgo and Centaurus clusters. Our results firmly favour models in which a
high mass fraction (70-80 per cent) of the iron in the X-ray gas in these
regions is due to Type Ia supernovae. Finally, we present a series of methods
which may be used to measure the ages of cooling flows from the X-ray data. The
results for the present sample of clusters indicate ages of between 2.5 and 7
Gyr. If the ages of cooling flows are primarily set by subcluster merger
events, then our results suggest that in the largest clusters, mergers with
subclusters with masses of approximately 30 per cent of the final cluster mass
are likely to disrupt cooling flows.Comment: Final version. MNRAS, in press. 36 pages, 9 figs, 14 tables in MNRAS
LaTex styl
Stochastic heating of cooling flows
It is generally accepted that the heating of gas in clusters of galaxies by
active galactic nuclei (AGN) is a form of feedback. Feedback is required to
ensure a long term, sustainable balance between heating and cooling. This work
investigates the impact of proportional stochastic feedback on the energy
balance in the intracluster medium. Using a generalised analytical model for a
cluster atmosphere, it is shown that an energy equilibrium can be reached
exponentially quickly. Applying the tools of stochastic calculus it is
demonstrated that the result is robust with regard to the model parameters,
even though they affect the amount of variability in the system.Comment: 7 pages, 6 figures, accepted by MNRAS,
http://www.astro.soton.ac.uk/~gbp/pub/pavlovski_stochh.pd
Structural stability of cooling flows
Three-dimensional hydrodynamical simulations are used to investigate the
structural stability of cooling flows that are episodically heated by jets from
a central AGN. The radial profile of energy deposition is controlled by (a) the
power of the jets, and (b) the pre-outburst density profile. A delay in the
ignition of the jets causes more powerful jets to impact on a more centrally
concentrated medium. The net effect is a sufficient increase in the central
concentration of energy deposition to cause the post-outburst density profile
to be less centrally concentrated than that of an identical cluster in which
the outburst happened earlier and was weaker. These results suggest that the
density profiles of cooling flows oscillate around an attracting profile, thus
explaining why cooling flows are observed to have similar density profiles. The
possibility is raised that powerful FR II systems are ones in which this
feedback mechanism has broken down and a runaway growth of the source
parameters has occurred.Comment: 4 pages, 2 figure
Heating cooling flows with jets
Active galactic nuclei are clearly heating gas in `cooling flows'. The
effectiveness and spatial distribution of the heating are controversial. We use
three-dimensional simulations on adaptive grids to study the impact on a
cooling flow of weak, subrelativistic jets. The simulations show cavities and
vortex rings as in the observations. The cavities are fast-expanding dynamical
objects rather than buoyant bubbles as previously modelled, but shocks still
remain extremely hard to detect with X-rays. At late times the cavities turn
into overdensities that strongly excite the cluster's g-modes. These modes damp
on a long timescale. Radial mixing is shown to be an important phenomenon, but
the jets weaken the metallicity gradient only very near the centre. The central
entropy density is modestly increased by the jets. We use a novel algorithm to
impose the jets on the simulations.Comment: 16 pages, 15 figures. Accepted for publication in MNRAS. Revised
version taking referee's comments into account, minor changes.
High-resolution version and MPEGs can be found at
http://www.clusterheating.org/papers.ph
Oxygen Absorption in Cooling Flows
The inhomogeneous cooling flow scenario predicts the existence of large
quantities of gas in massive elliptical galaxies, groups, and clusters that
have cooled and dropped out of the flow. Using spatially resolved, deprojected
X-ray spectra from the ROSAT PSPC we have detected strong absorption over
energies ~0.4-0.8 keV intrinsic to the central ~1 arcmin of the galaxy, NGC
1399, the group, NGC 5044, and the cluster, A1795. These systems have amongst
the largest nearby cooling flows in their respective classes and low Galactic
columns. Since no excess absorption is indicated for energies below ~0.4 keV
the most reasonable model for the absorber is warm, collisionally ionized gas
with T=10^{5-6} K where ionized states of oxygen provide most of the
absorption. Attributing the absorption only to ionized gas reconciles the large
columns of cold H and He inferred from Einstein and ASCA with the lack of such
columns inferred from ROSAT, and also is consistent with the negligible atomic
and molecular H inferred from HI, and CO observations of cooling flows. The
prediction of warm ionized gas as the product of mass drop-out in these and
other cooling flows can be verified by Chandra, XMM, and ASTRO-E.Comment: 4 pages (2 figures), Accepted for publication in ApJ Letters, no
significant changes from previous submitted versio
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