2,690 research outputs found
Cluster temperatures and non-extensive thermo-statistics
We propose a novel component to the understanding of the temperature
structure of galaxy clusters which does not rely on any heating or cooling
mechanism. The new ingredient is the use of non-extensive thermo-statistics
which is based on the natural generalization of entropy for systems with
long-range interactions. Such interactions include gravity and attraction or
repulsion due to charges. We explain that there is growing theoretical
indications for the need of this generalization for large cosmological
structures. The observed pseudo temperature is generally different from the
true thermodynamic temperature, and we clarify the connection between the two.
We explain that this distinction is most important in the central part of the
cluster where the density profile is most shallow. We show that the observed
pseudo temperature may differ up to a factor 2/5 from the true thermodynamic
temperature, either larger or smaller. In general the M-T and L-T relations
will be affected, and the central DM slope derived through hydrostatic
equilibrium may be either more shallow or steeper. We show how the true
temperature can be extracted correctly either from the spectrum or from the
shape of the Doppler broadening of spectral lines.Comment: 11 pages, 1 figur
The behaviour of shape and velocity anisotropy in dark matter haloes
Dark matter haloes from cosmological N-body simulations typically have
triaxial shapes and anisotropic velocity distributions. Recently it has been
shown that the velocity anisotropy, beta, of cosmological haloes and major
merger remnants depends on direction in such a way that beta is largest along
the major axis and smallest along the minor axis. In this work we use a wide
range of non-cosmological N-body simulations to examine halo shapes and
direction-dependence of velocity anisotropy profiles. For each of our simulated
haloes we define 48 cones pointing in different directions, and from the
particles inside each cone we compute velocity anisotropy profiles. We find
that elongated haloes can have very distinct velocity anisotropies. We group
the behaviour of haloes into three different categories, that range from
spherically symmetric profiles to a much more complex behaviour, where
significant differences are found for beta along the major and minor axes. We
encourage future studies of velocity anisotropies in haloes from cosmological
simulations to calculate beta-profiles in cones, since it reveals information,
which is hidden from a spherically averaged profile. Finally, we show that
spherically averaged profiles often obey a linear relation between beta and the
logarithmic density slope in the inner parts of haloes, but this relation is
not necessarily obeyed, when properties are calculated in cones.Comment: 23 pages, 14 figures. Accepted for publication in JCA
Asymmetric velocity anisotropies in remnants of collisionless mergers
Dark matter haloes in cosmological N-body simulations are affected by
processes such as mergers, accretion and the gravitational interaction with
baryonic matter. Typically the analysis of dark matter haloes is performed in
spherical or elliptical bins and the velocity distributions are often assumed
to be constant within those bins. However, the velocity anisotropy, which
describes differences between the radial and tangential velocity dispersion,
has recently been show to have a strong dependence on direction in the triaxial
halos formed in cosmological simulations. In this study we derive properties of
particles in cones parallel or perpendicular to the collision axis of merger
remnants. We find that the velocity anisotropy has a strong dependence on
direction. The finding that the direction-dependence of the velocity anisotropy
of a halo depends on the merger history, explains the existence of such trends
in cosmological simulations. It also explains why a large diversity is seen in
the velocity anisotropy profiles in the outer parts of high-resolution
simulations of cosmological haloes.Comment: 19 pages, 15 figures, Resubmitted to JCAP after referee comment
Observational constraints on the inflaton potential combined with flow-equations in inflaton space
Direct observations provide constraints on the first two derivatives of the
inflaton potential in slow roll models. We discuss how present day
observations, combined with the flow equations in slow roll parameter space,
provide a non-trivial constraint on the third derivative of the inflaton
potential. We find a lower bound on the third derivative of the inflaton
potential V'''/V > -0.2. We also show that unless the third derivative of the
inflaton potential is unreasonably large, then one predicts the tensor to
scalar ratio, r, to be bounded from below r > 3 * 10^{-6}.Comment: 4 pages, 2 figures. Important sign mistake corrected. Conclusions,
abstract and discussion change
Effect of asphericity in caustic mass estimates of galaxy clusters
The caustic technique for measuring mass profiles of galaxy clusters relies
on the assumption of spherical symmetry. When applied to aspherical galaxy
clusters, the method yields mass estimates affected by the cluster orientation.
Here we employ mock redshift catalogues generated from cosmological simulations
to study the effect of clusters intrinsic shape and surrounding filamentary
structures on the caustic mass estimates. To this end, we develop a new method
for removing perturbations from large-scale structures, modelled as the
two-halo term, in a caustic analysis of stacked cluster data.
We find that the cluster masses inferred from kinematical data of ~10^14 Msun
clusters observed along the major axis are larger than masses from those
observed along the minor axis by a factor of 1.7 within the virial radius,
increasing to 1.8 within three virial radii. This discrepancy increases by 20%
for the most massive clusters. In addition a smaller but still significant mass
discrepancy arises when filamentary structures are present near a galaxy
cluster.
We find that the mean cluster mass from random sightlines is unbiased at all
radii and their scatter ranges from 0.14 to 0.17 within one and three virial
radii, with a 40% increase for the most massive clusters. We provide tables
which estimate the caustic mass bias given observational constraints on the
cluster orientation.Comment: 19 pages, 9 figures, 6 tables, accepted for publication in MNRA
Analytical derivation of the radial distribution function in spherical dark matter halos
The velocity distribution of dark matter near the Earth is important for an
accurate analysis of the signals in terrestrial detectors. This distribution is
typically extracted from numerical simulations. Here we address the possibility
of deriving the velocity distribution function analytically. We derive a
differential equation which is a function of radius and the radial component of
the velocity. Under various assumptions this can be solved, and we compare the
solution with the results from controlled numerical simulations. Our findings
complement the previously derived tangential velocity distribution. We hereby
demonstrate that the entire distribution function, below 0.7 v_esc, can be
derived analytically for spherical and equilibrated dark matter structures.Comment: 6 pages, 5 figures, submitted to MNRA
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