1,360 research outputs found
Evidence for high inter-granular current flow in single-phase polycrystalline MgB2 superconductor
The distribution of magnetic field in single-phase polycrystalline bulk MgB2
has been measured using a Magneto-Optical (MO) technique for an external
magnetic field applied perpendicular to the sample surface. The MO studies
indicate that an inter-granular current network is readily established in this
material and the current is not limited by weak-linked grain boundaries. The
grain boundaries are observed to resist preferential magnetic field
penetration, with the inter-grain mechanism dominating the current flow in the
sample at temperatures up to 30K. The results provide clear evidence that the
intra-granular current flow is isotropic. A critical current density of ~10^4
Acm-2 was estimated at 30K in a field of 150mT from the MO measurements. These
results provide further evidence of the considerable potential for MgB2 for
engineering applications.Comment: 3 pages, 3 figure
A 120-Mpc Periodicity in the Three-Dimensional Distribution of Galaxy Superclusters
Using a new compilation of available data on galaxy clusters and
superclusters we present evidence for a quasiregular three-dimensional network
of rich superclusters and voids, with the regions of high density separated by
about 120 Mpc. We calculate the power spectrum for clusters of galaxies; it has
a peak on the wavelength equal to the step of the network; the excess in the
amplitude of the spectrum over that of the cold dark matter model is by a
factor of 1.4. The probability that the spectrum can be formed within the
framework of the standard cosmogony is very small. If the cluster distribution
reflects the distribution of all matter (luminous and dark), then there must
exists some hithero unknown process that produces regular structure on large
scales.Comment: Tex, 6 pages, 2 PostScript figures embedded, accepted by Nature on
November 19, 199
Eccentric black hole-neutron star mergers: effects of black hole spin and equation of state
There is a high level of interest in black hole-neutron star binaries, not
only because their mergers may be detected by gravitational wave observatories
in the coming years, but also because of the possibility that they could
explain a class of short duration gamma-ray bursts. We study black hole-neutron
star mergers that occur with high eccentricity as may arise from dynamical
capture in dense stellar regions such as nuclear or globular clusters. We
perform general relativistic simulations of binaries with a range of impact
parameters, three different initial black hole spins (zero, aligned and
anti-aligned with the orbital angular momentum), and neutron stars with three
different equations of state. We find a rich diversity across these parameters
in the resulting gravitational wave signals and matter dynamics, which should
also be reflected in the consequent electromagnetic emission. Before tidal
disruption, the gravitational wave emission is significantly larger than
perturbative predictions suggest for periapsis distances close to effective
innermost stable separations, exhibiting features reflecting the zoom-whirl
dynamics of the orbit there. Guided by the simulations, we develop a simple
model for the change in orbital parameters of the binary during close
encounters. Depending upon the initial parameters of the system, we find that
mass transfer during non-merging close encounters can range from essentially
zero to a sizable fraction of the initial neutron star mass. The same holds for
the amount of material outside the black hole post-merger, and in some cases
roughly half of this material is estimated to be unbound. We also see that
non-merging close encounters generically excite large oscillations in the
neutron star that are qualitatively consistent with f-modes.Comment: 19 pages, 13 figures, revised according to referee comment
Microstructure and superconducting properties of hot isostatically pressed MgB2
Bulk samples of MgB2 have been formed by hot isostatic pressing (HIPping) of
commercial powder at 100MPa and 950=B0C. The resulting material is 100% dense
with a sharp superconducting transition at 37.5K. Microstructural studies have
indicated the presence of small amounts of second phases within the material,
namely MgO and B rich compositions, probably MgB4. Magnetisation measurements
performed at 20K have revealed values of Jc=1.3 x 106A/cm2 at zero field, and
9.3 x 105A/cm2 at 1T. Magneto optical (MO) studies have shown direct evidence
for the superconducting homogeneity and strong intergranular current flow in
the material.Comment: 3 pages, 6 figures, text updated, new references included and
discussed. Submitted to Superconductor Science and Technolog
An organic fluorophore-nanodiamond hybrid sensor for photostable imaging and orthogonal, on-demand biosensing
Organic fluorescent probes are widely used to detect key biomolecules; however, they often lack the photostability required for extended intracellular imaging. Here we report a new hybrid nanomaterial (peroxynanosensor, PNS), consisting of an organic fluorescent probe bound to a nanodiamond, that overcomes this limitation to allow concurrent and extended cell-based imaging of the nanodiamond and ratiometric detection of hydrogen peroxide. Far-red fluorescence of the nanodiamond offers continuous monitoring without photobleaching, while the green fluorescence of the organic fluorescent probe attached to the nanodiamond surface detects hydrogen peroxide on demand. PNS detects basal production of hydrogen peroxide within M1 polarised macrophages and does not affect macrophage growth during prolonged co-incubation. This nanosensor can be used for extended bio-imaging not previously possible with an organic fluorescent probe, and is spectrally compatible with both Hoechst 33342 and MitoTracker Orange stains for hyperspectral imaging.Malcolm S. Purdey, Patrick K. Capon, Benjamin J. Pullen, Philipp Reineck,
Nisha Schwarz, Peter J. Psaltis, Stephen J. Nicholls, Brant C. Gibson and
Andrew D. Abel
Modeling of Covalent Bonding in Solids by Inversion of Cohesive Energy Curves
We provide a systematic test of empirical theories of covalent bonding in
solids using an exact procedure to invert ab initio cohesive energy curves. By
considering multiple structures of the same material, it is possible for the
first time to test competing angular functions, expose inconsistencies in the
basic assumption of a cluster expansion, and extract general features of
covalent bonding. We test our methods on silicon, and provide the direct
evidence that the Tersoff-type bond order formalism correctly describes
coordination dependence. For bond-bending forces, we obtain skewed angular
functions that favor small angles, unlike existing models. As a
proof-of-principle demonstration, we derive a Si interatomic potential which
exhibits comparable accuracy to existing models.Comment: 4 pages revtex (twocolumn, psfig), 3 figures. Title and some wording
(but no content) changed since original submission on 24 April 199
Global survey of star clusters in the Milky Way: III. 139 new open clusters at high Galactic latitudes
Context. An earlier analysis of the Milky Way Star Cluster (MWSC) catalogue revealed an apparent lack of old (t � 1 Gyr) open clusters in the solar neighbourhood (d � 1 kpc). Aims. To fill this gap we undertook a search for hitherto unknown star clusters, assuming that the missing old clusters reside at high Galactic latitudes | b | > 20°. Methods. We were looking for stellar density enhancements using a star count algorithm on the 2MASS point source catalogue. To increase the contrast between potential clusters and the field, we applied filters in colour-magnitude space according to typical colour-magnitude diagrams of nearby old open clusters. The subsequent comparison with lists of known objects allowed us to select thus far unknown cluster candidates. For verification they were processed with the standard pipeline used within the MWSC survey for computing cluster membership probabilities and for determining structural, kinematic, and astrophysical parameters. Results. In total we discovered 782 density enhancements, 524 of which were classified as real objects. Among them 139 are new open clusters with ages 8.3 < log (t [yr]) < 9.7, distances d< 3 kpc, and distances from the Galactic plane 0.3 <Z< 1 kpc. This new sample has increased the total number of known high latitude open clusters by about 150%. Nevertheless, we still observe a lack of older nearby clusters up to 1 kpc from the Sun. This volume is expected to still contain about 60 unknown clusters that probably escaped our detection algorithm, which fails to detect sparse overdensities with large angular size
4098 galaxy clusters to z~0.6 in the Sloan Digital Sky Survey equatorial Stripe 82
We present a catalogue of 4098 photometrically selected galaxy clusters with
a median redshift = 0.32 in the 270 square degree 'Stripe 82' region of the
Sloan Digital Sky Survey (SDSS), covering the celestial equator in the Southern
Galactic Cap (-50 < RA < 59 deg, |Dec| < 1.25 deg). Owing to the multi-epoch
SDSS coverage of this region, the ugriz photometry is ~2 magnitudes deeper than
single scans within the main SDSS footprint. We exploit this to detect clusters
of galaxies using an algorithm that searches for statistically significant
overdensities of galaxies in a Voronoi tessellation of the projected sky. 32%
of the clusters have at least one member with a spectroscopic redshift from
existing public data (SDSS Data Release 7, 2SLAQ & WiggleZ), and the remainder
have a robust photometric redshift (accurate to ~5-9% at the median redshift of
the sample). The weighted average of the member galaxies' redshifts provides a
reasonably accurate estimate of the cluster redshift. The cluster catalogue is
publicly available for exploitation by the community to pursue a range of
science objectives. In addition to the cluster catalogue, we provide a linked
catalogue of 18,295 V<21 mag quasar sight-lines with impact parameters within
<3 Mpc of the cluster cores selected from the catalogue of Veron et al. (2010).
The background quasars cover 0.25 < z < 2, where MgII absorption-line systems
associated with the clusters are detectable in optical spectra.Comment: 10 pages, 2 figures, accepted for publication in MNRAS. Catalogues
available at http://www.physics.mcgill.ca/~jimgeach/stripe8
Peculiar Motions in the Region of the Ursa Major Supercluster of Galaxies
We have investigated the peculiar motions of clusters of galaxies in the Ursa
Major (UMa) supercluster and its neighborhood. Based on SDSS (Sloan Digital Sky
Survey) data, we have compiled a sample of early-type galaxies and used their
fundamental plane to determine the cluster distances and peculiar velocities.
The samples of early-type galaxies in the central regions (within R_200) of 12
UMa clusters of galaxies, in three main subsystems of the supercluster -- the
filamentary structures connecting the clusters, and in nine clusters from the
nearest UMa neighborhood have similar parameters. The fairly high overdensity
(3 by the galaxy number and 15 by the cluster number) suggests that the
supercluster as a whole is gravitationally bound, while no significant peculiar
motions have been found: the peculiar velocities do not exceed the measurement
errors by more than a factor of 1.5-2. The mean random peculiar velocities of
clusters and the systematic deviations from the overall Hubble expansion in the
supercluster are consistent with theoretical estimates. For the possible
approach of the three UMa subsystems to be confirmed, the measurement accuracy
must be increased by a factor of 2-3.Comment: 21 pages, 4 tables, 7 figure
How accurate is it to update the cosmology of your halo catalogues?
We test and present the application of the full rescaling method by Angulo &
White (2010) to change the cosmology of halo catalogues in numerical
simulations for cosmological parameter search using semi-analytic galaxy
properties. We show that a reduced form of the method can be applied in small
simulations with box side of ~50/h Mpc. We perform statistical tests on the
accuracy of the properties of rescaled individual haloes, and also on the
rescaled population as a whole. We find that individual positions and
velocities are recovered with almost no detectable biases. The dispersion in
the recovered halo mass does not seem to depend on the resolution of the
simulation. Regardless of the halo mass, the individual accretion histories,
spin parameter evolution and fraction of mass in substructures are well
recovered. The mass of rescaled haloes can be underestimated (overestimated)
for negative (positive) variations of either sigma_8 or Omega_m, in a way that
does not depend on the halo mass. Statistics of abundances and correlation
functions of haloes show also small biases of <10 percent when moving away from
the base simulation by up to 2 times the uncertainty in the WMAP7 cosmological
parameters. The merger tree properties related to the final galaxy population
in haloes also show small biases; the time since the last major merger, the
assembly time-scale, and a time-scale related to the stellar ages show
correlated biases which indicate that the spectral shapes of galaxies would
only be affected by global age changes of ~150 Myr. We show some of these
biases for different separations in the cosmological parameters with respect to
the desired cosmology so that these can be used to estimate the expected
accuracy of the resulting halo population. We also present a way to construct
grids of simulations to provide stable accuracy across the Omega_m vs sigma_8
parameter space.Comment: 14 pages, 2 tables, 10 figures. Accepted for publication in MNRA
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