3,646 research outputs found
CP Test in the W Pair Production via Photon Fusion at NLC
We study the possibility to test CP invariance in the production via
photon fusion at NLC. The predictions of the CP violation effects are made
within two Higgs doublet extensions of the minimal standard model, where CP
violation is introduced by a neutral Higgs exchange in s channel in our case.
The width effect in the Higgs propagator on the CP violation effects is studied
in detail. The CP violation effects can be measured in some parameter region of
the extensions.Comment: 11 pages, Tex, UM-P-93/16, OZ-93/6 One figure not include
Spin Resolution of the Electron-Gas Correlation Energy: Positive same-spin contribution
The negative correlation energy per particle of a uniform electron gas of
density parameter and spin polarization is well known, but its
spin resolution into up-down, up-up, and down-down contributions is not.
Widely-used estimates are incorrect, and hamper the development of reliable
density functionals and pair distribution functions. For the spin resolution,
we present interpolations between high- and low-density limits that agree with
available Quantum Monte Carlo data. In the low-density limit for ,
we find that the same-spin correlation energy is unexpectedly positive, and we
explain why. We also estimate the up and down contributions to the kinetic
energy of correlation.Comment: new version, to appear in PRB Rapid Communicatio
Field desorption ion source development for neutron generators
A new approach to deuterium ion sources for deuterium-tritium neutron
generators is being developed. The source is based upon the field desorption of
deuterium from the surfaces of metal tips. Field desorption studies of
microfabricated field emitter tip arrays have been conducted for the first
time. Maximum fields of 30 V/nm have been applied to the array tip surfaces to
date, although achieving fields of 20 V/nm to possibly 25 V/nm is more typical.
Both the desorption of atomic deuterium ions and the gas phase field ionization
of molecular deuterium has been observed at fields of roughly 20 V/nm and 20-30
V/nm, respectively, at room temperature. The desorption of common surface
adsorbates, such as hydrogen, carbon, water, and carbon monoxide is observed at
fields exceeding ~10 V/nm. In vacuo heating of the arrays to temperatures of
the order of 800 C can be effective in removing many of the surface
contaminants observed
Inherent thermometry in a hybrid superconducting tunnel junction
We discuss inherent thermometry in a Superconductor - Normal metal -
Superconductor tunnel junction. In this configuration, the energy selectivity
of single-particle tunneling can provide a significant electron cooling,
depending on the bias voltage. The usual approach for measuring the electron
temperature consists in using an additional pair of superconducting tunnel
junctions as probes. In this paper, we discuss our experiment performed on a
different design with no such thermometer. The quasi-equilibrium in the central
metallic island is discussed in terms of a kinetic equation including injection
and relaxation terms. We determine the electron temperature by comparing the
micro-cooler experimental current-voltage characteristic with isothermal
theoretical predictions. The limits of validity of this approach, due to the
junctions asymmetry, the Andreev reflection or the presence of sub-gap states
are discussed
Efficient photon counting and single-photon generation using resonant nonlinear optics
The behavior of an atomic double lambda system in the presence of a strong
off-resonant classical field and a few-photon resonant quantum field is
examined. It is shown that the system possesses properties that allow a
single-photon state to be distilled from a multi-photon input wave packet. In
addition, the system is also capable of functioning as an efficient
photodetector discriminating between one- and two-photon wave packets with
arbitrarily high efficiency.Comment: 4 pages, 2 figure
Quicksort, Largest Bucket, and Min-Wise Hashing with Limited Independence
Randomized algorithms and data structures are often analyzed under the
assumption of access to a perfect source of randomness. The most fundamental
metric used to measure how "random" a hash function or a random number
generator is, is its independence: a sequence of random variables is said to be
-independent if every variable is uniform and every size subset is
independent. In this paper we consider three classic algorithms under limited
independence. We provide new bounds for randomized quicksort, min-wise hashing
and largest bucket size under limited independence. Our results can be
summarized as follows.
-Randomized quicksort. When pivot elements are computed using a
-independent hash function, Karloff and Raghavan, J.ACM'93 showed expected worst-case running time for a special version of quicksort.
We improve upon this, showing that the same running time is achieved with only
-independence.
-Min-wise hashing. For a set , consider the probability of a particular
element being mapped to the smallest hash value. It is known that
-independence implies the optimal probability . Broder et al.,
STOC'98 showed that -independence implies it is . We show
a matching lower bound as well as new tight bounds for - and -independent
hash functions.
-Largest bucket. We consider the case where balls are distributed to
buckets using a -independent hash function and analyze the largest bucket
size. Alon et. al, STOC'97 showed that there exists a -independent hash
function implying a bucket of size . We generalize the
bound, providing a -independent family of functions that imply size .Comment: Submitted to ICALP 201
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An ion trap built with photonic crystal fibre technology
We demonstrate a surface-electrode ion trap fabricated using techniques transferred from the manufacture of photonic-crystal fibres. This provides a relatively straightforward route for realizing traps with an electrode structure on the 100 micron scale with high optical access. We demonstrate the basic functionality of the trap by cooling a single ion to the quantum ground state, allowing us to measure a heating rate from the ground state of 787 ± 24 quanta/s. Variation of the fabrication procedure used here may provide access to traps in this geometry with trap scales between 100 μm and 10 μ
Transport of charged particles by adjusting rf voltage amplitudes
We propose a planar architecture for scalable quantum information processing
(QIP) that includes X-junctions through which particles can move without
micromotion. This is achieved by adjusting radio frequency (rf) amplitudes to
move an rf null along the legs of the junction. We provide a proof-of-principle
by transporting dust particles in three dimensions via adjustable rf potentials
in a 3D trap. For the proposed planar architecture, we use regularization
techniques to obtain amplitude settings that guarantee smooth transport through
the X-junction.Comment: 16 pages, 10 figure
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