4,842 research outputs found
The Environments of SLACS Gravitational Lenses
We report on an investigation of the environments of the SLACS sample of
gravitational lenses. The local and global environments of the lenses are
characterized using SDSS photometry and, when available, spectroscopy. We find
that the lens systems that are best modelled with steeper than isothermal
density profiles are more likely to have close companions than lenses with
shallower than isothermal profiles. This suggests that the profile steepening
may be caused by interactions with a companion galaxy as indicated by N-body
simulations of group galaxies. The global environments of the SLACS lenses are
typical of non-lensing SDSS galaxies with comparable properties to the lenses,
and the richnesses of the lens groups are not as strongly correlated with the
lens density profiles as the local environments. Furthermore, we investigate
the possibility of line-of-sight contamination affecting the lens models but do
not find a significant over-density of sources compared to lines of sight
without lenses.Comment: 5 pages, 4 figures, accepted for publication in MNRA
Atmospheric Calorimetry above 10 eV: Shooting Lasers at the Pierre Auger Cosmic-Ray Observatory
The Pierre Auger Cosmic-Ray Observatory uses the earth's atmosphere as a
calorimeter to measure extensive air-showers created by particles of
astrophysical origin. Some of these particles carry joules of energy. At these
extreme energies, test beams are not available in the conventional sense. Yet
understanding the energy response of the observatory is important. For example,
the propagation distance of the highest energy cosmic-rays through the cosmic
microwave background radiation (CMBR) is predicted to be strong function of
energy. This paper will discuss recently reported results from the observatory
and the use of calibrated pulsed UV laser "test-beams" that simulate the
optical signatures of ultra-high energy cosmic rays. The status of the much
larger 200,000 km companion detector planned for the northern hemisphere
will also be outlined.Comment: 6 pages, 11 figures XIII International Conference on Calorimetry in
High Energy Physic
The Environments of Low and High Luminosity Radio Galaxies at Moderate Redshifts
In the local Universe, high-power radio galaxies live in lower density
environments than low-luminosity radio galaxies. If this trend continues to
higher redshifts, powerful radio galaxies would serve as efficient probes of
moderate redshift groups and poor clusters. Photometric studies of radio
galaxies at 0.3 < z < 0.5 suggest that the radio luminosity-environment
correlation disappears at moderate redshifts, though this could be the result
of foreground/background contamination affecting the photometric measures of
environment. We have obtained multi-object spectroscopy of in the fields of 14
lower luminosity (L_1.4GHz
1.2x10^25 W/Hz) radio galaxies at z ~ 0.3 to spectroscopically investigate the
link between the environment and the radio luminosity of radio galaxies at
moderate redshifts. Our results support the photometric analyses; there does
not appear to be a correlation between the luminosity of a radio galaxy and its
environment at moderate redshifts. Hence, radio galaxies are not efficient
signposts for group environments at moderate redshifts.Comment: 7 pages, 9 figures, Accepted for publication in A
Radio-mode feedback in local AGNs: dependence on the central black hole parameters
Radio mode feedback, in which most of the energy of an active galactic
nucleus (AGN) is released in a kinetic form via radio-emitting jets, is thought
to play an important role in the maintenance of massive galaxies in the
present-day Universe. We study the link between radio emission and the
properties of the central black hole in a large sample of local radio galaxies
drawn from the Sloan Digital Sky Survey (SDSS), based on the catalogue of Best
and Heckman (2012). Our sample is mainly dominated by massive black holes
(mostly in the range ) accreting at very low Eddington
ratios (typically ). In broad agreement with previously
reported trends, we find that radio galaxies are preferentially associated with
the more massive black holes, and that the radio loudness parameter seems to
increase with decreasing Eddington ratio. We compare our results with previous
studies in the literature, noting potential biases. The majority of the local
radio galaxies in our sample are currently in a radiatively inefficient
accretion regime, where kinetic feedback dominates over radiative feedback. We
discuss possible physical interpretations of the observed trends in the context
of a two-stage feedback process involving a transition in the underlying
accretion modes.Comment: accepted for publication in Monthly Notices of the Royal Astronomical
Societ
Blueprint for fault-tolerant quantum computation with Rydberg atoms
We present a blueprint for building a fault-tolerant universal quantum computer with Rydberg atoms. Our scheme, which is based on the surface code, uses individually addressable, optically trapped atoms as qubits and exploits electromagnetically induced transparency to perform the multiqubit gates required for error correction and computation. We discuss the advantages and challenges of using Rydberg atoms to build such a quantum computer, and we perform error correction simulations to obtain an error threshold for our scheme. Our findings suggest that Rydberg atoms are a promising candidate for quantum computation, but gate fidelities need to improve before fault-tolerant universal quantum computation can be achieved
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