4,592 research outputs found
A posteriori inclusion of PDFs in NLO QCD final-state calculations
Any NLO calculation of a QCD final-state observable involves Monte Carlo
integration over a large number of events. For DIS and hadron colliders this
must usually be repeated for each new PDF set, making it impractical to
consider many `error' PDF sets, or carry out PDF fits. Here we discuss ``a
posteriori'' inclusion of PDFs, whereby the Monte Carlo run calculates a grid
(in x and Q) of cross section weights that can subsequently be combined with an
arbitrary PDF. The procedure is numerically equivalent to using an interpolated
form of the PDF. The main novelty relative to prior work is the use of
higher-order interpolation, which substantially improves the tradeoff between
accuracy and memory use. An accuracy of about 0.01% has been reached for the
single inclusive cross-section in the central rapidity region |y|<0.5 for jet
transverse momenta from 100 to 5000 GeV. This method should facilitate the
consistent inclusion of final-state data from HERA, Tevatron and LHC in PDF
fits, thus helping to increase the sensitivity of LHC to deviations from
standard Model predictions.Comment: contribution to the CERN DESY workshop on "HERA and LHC
Identification of type A and B isolates of Epstein-Barr virus by polymerase chain reaction
A method is described for the identification of type A and type B isolates of Epstein-Barr virus (EBV) by means of the polymerase chain reaction. The use of three pairs of primers specific for genomic sequences coding for the two forms of EBV nuclear antigen (EBNA), 2A and 2B, and for a DNA sequence from the BamZ/BamR region allows the reliable and rapid detection of type A and B viruses in as little as 1000 EBV positive cells
Coarsening Dynamics of Crystalline Thin Films
The formation of pyramid-like structures in thin-film growth on substrates
with a quadratic symmetry, e.g., {001} surfaces, is shown to exhibit
anisotropic scaling as there exist two length scales with different time
dependences. Analytical and numerical results indicate that for most
realizations coarsening of mounds is described by an exponent n=0.2357.
However, depending on material parameters, n may lie between 0 (logarithmic
coarsening) and 1/3. In contrast, growth on substrates with triangular
symmetries ({111} surfaces) is dominated by a single length scale and an
exponent n=1/3.Comment: RevTeX, 4 pages, 3 figure
Mean Field and the Single Homopolymer
We develop a statistical model for a confined chain molecule based on a
monomer grand canonical ensemble. The molecule is subject to an external
chemical potential, a backbone interaction, and an attractive interaction
between all monomers. Using a Gaussian variable formalism and a mean field
approximation, we analytically derive a minimum principle from which we can
obtain relevant physical quantities, such as the monomer density, and we
explore the limit in which the chain is subject to a tight confinement. Through
a numerical implementation of the minimization process we show how we can
obtain density profiles in three dimensions for arbitraty potentials, and we
test the limits of validity of the theory.Comment: 15 pages, 7 figure
Stochastic method for in-situ damage analysis
Based on the physics of stochastic processes we present a new approach for
structural health monitoring. We show that the new method allows for an in-situ
analysis of the elastic features of a mechanical structure even for realistic
excitations with correlated noise as it appears in real-world situations. In
particular an experimental set-up of undamaged and damaged beam structures was
exposed to a noisy excitation under turbulent wind conditions. The method of
reconstructing stochastic equations from measured data has been extended to
realistic noisy excitations like those given here. In our analysis the
deterministic part is separated from the stochastic dynamics of the system and
we show that the slope of the deterministic part, which is linked to mechanical
features of the material, changes sensitively with increasing damage. The
results are more significant than corresponding changes in eigenfrequencies, as
commonly used for structural health monitoring.Comment: This paper is accepted by European Physical Journal B on November 2.
2012. 5 pages, 5 figures, 1 tabl
Quenched QCD with domain wall fermions
We report on simulations of quenched QCD using domain wall fermions, where we
focus on basic questions about the formalism and its ability to produce
expected low energy hadronic physics for light quarks. The work reported here
is on quenched lattices at and 5.85, using values
for the length of the fifth dimension between 10 and 48. We report results for
parameter choices which lead to the desired number of flavors, a study of
undamped modes in the extra dimension and hadron masses.Comment: Contribution to Lattice '98. Presented by R. Mawhinney. 3 pages, 3
figure
Dynamical QCD thermodynamics with domain wall fermions
We present results from numerical simulations of full, two flavor QCD
thermodynamics at N_t=4 with domain wall fermions. For the first time a
numerical simulation of the full QCD phase transition displays a low
temperature phase with spontaneous chiral symmetry breaking but intact flavor
symmetry and a high temperature phase with the full SU(2) x SU(2) chiral flavor
symmetry.Comment: LATTICE98(hightemp
Nonmonotonic roughness evolution in unstable growth
The roughness of vapor-deposited thin films can display a nonmonotonic
dependence on film thickness, if the smoothening of the small-scale features of
the substrate dominates over growth-induced roughening in the early stage of
evolution. We present a detailed analysis of this phenomenon in the framework
of the continuum theory of unstable homoepitaxy. Using the spherical
approximation of phase ordering kinetics, the effect of nonlinearities and
noise can be treated explicitly. The substrate roughness is characterized by
the dimensionless parameter , where denotes the
roughness amplitude, is the small scale cutoff wavenumber of the
roughness spectrum, and is the lattice constant. Depending on , the
diffusion length and the Ehrlich-Schwoebel length , five regimes
are identified in which the position of the roughness minimum is determined by
different physical mechanisms. The analytic estimates are compared by numerical
simulations of the full nonlinear evolution equation.Comment: 16 pages, 6 figures, to appear on Phys. Rev.
The domain wall fermion chiral condensate in quenched QCD
We examine the chiral limit of domain wall fermions in quenched QCD. One
expects that in a quenched simulation, exact fermion zero modes will give a
divergent, 1/m behavior in the chiral condensate for sufficiently small valence
quark masses. Unlike other fermion formulations, domain wall fermions clearly
demonstrate this behavior.Comment: LATTICE98(spectrum), G. R. Fleming presented talk, 5 pages, 3
figures, corrected typos in printed versio
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