7,395 research outputs found
Dihadron Fragmentation Functions in the NJL-jet model
The NJL-jet model provides a framework for calculating fragmentation
functions without introducing ad hoc parameters. Here the NJL-jet model is
extended to investigate dihadron fragmentation functions.Comment: 4 pages, 5 figures, Proceedings of 8th Circum-Pan-Pacific Symposium
on High Energy Spin Physic
UVMULTIFIT: A versatile tool for fitting astronomical radio interferometric data
The analysis of astronomical interferometric data is often performed on the
images obtained after deconvolution of the interferometer's point spread
function (PSF). This strategy can be understood (especially for cases of sparse
arrays) as fitting models to models, since the deconvolved images are already
non-unique model representations of the actual data (i.e., the visibilities).
Indeed, the interferometric images may be affected by visibility gridding,
weighting schemes (e.g., natural vs. uniform), and the particulars of the
(non-linear) deconvolution algorithms. Fitting models to the direct
interferometric observables (i.e., the visibilities) is preferable in the cases
of simple (analytical) sky intensity distributions. In this paper, we present
UVMULTIFIT, a versatile library for fitting visibility data, implemented in a
Python-based framework. Our software is currently based on the CASA package,
but can be easily adapted to other analysis packages, provided they have a
Python API. We have tested the software with synthetic data, as well as with
real observations. In some cases (e.g., sources with sizes smaller than the
diffraction limit of the interferometer), the results from the fit to the
visibilities (e.g., spectra of close by sources) are far superior to the output
obtained from the mere analysis of the deconvolved images. UVMULTIFIT is a
powerful improvement of existing tasks to extract the maximum amount of
information from visibility data, especially in cases close to the
sensitivity/resolution limits of interferometric observations.Comment: 10 pages, 4 figures. Accepted in A&A. Code available at
http://nordic-alma.se/support/software-tool
Magnetocaloric effect in Gd/W thin film heterostructures
In an effort to understand the impact of nanostructuring on the
magnetocaloric effect, we have grown and studied gadolinium in MgO/W(50
)/[Gd(400 )/W(50 )]
heterostructures. The entropy change associated with the second order magnetic
phase transition was determined from the isothermal magnetization for numerous
temperatures and the appropriate Maxwell relation. The entropy change peaks at
a temperature of 284 K with a value of approximately 3.4 J/kg-K for a 0-30 kOe
field change; the full width at half max of the entropy change peak is about 70
K, which is significantly wider than that of bulk Gd under similar conditions.
The relative cooling power of this nanoscale system is about 240 J/kg, somewhat
lower than that of bulk Gd (410 J/kg). An iterative Kovel-Fisher method was
used to determine the critical exponents governing the phase transition to be
, and . Along with a suppressed Curie temperature
relative to the bulk, the fact that the convergent value of is that
predicted by the 2-D Ising model may suggest that finite size effects play an
important role in this system. Together, these observations suggest that
nanostructuring may be a promising route to tailoring the magnetocaloric
response of materials
The Effect of Certain Chemical Treatments on Photolytic Image Formation
A study of certain chemical baths and combinations of chemical baths was made to determine their effect on the print-out image of a specially-prepared conventional developing-out enlarging paper. These Print-out images were formed and made visible entirely from the photolytic effect of the image exposure. Arc lamp, tungsten lamp and electronic flash lamp exposures were made; arc lamp exposures were the most satisfactory. The chemical associated with the most image improvement was stannous chloride
Dynamics of Spontaneous Magnetization Reversal in Exchange Biased Heterostructures
The dependence of thermally induced spontaneous magnetization reversal on
time-dependent cooling protocols was studied. Slower cooling and longer waiting
close to the N\`{e}el temperature of the antiferromagnet () enhances the
magnetization reversal. Cycling the temperature around leads to a thermal
training effect under which the reversal magnitude increases with each cycle.
These results suggest that spontaneous magnetization reversal is energetically
favored, contrary to our present understanding of positive exchange bias
Uncertainties of predictions from parton distribution functions II: the Hessian method
We develop a general method to quantify the uncertainties of parton
distribution functions and their physical predictions, with emphasis on
incorporating all relevant experimental constraints. The method uses the
Hessian formalism to study an effective chi-squared function that quantifies
the fit between theory and experiment. Key ingredients are a recently developed
iterative procedure to calculate the Hessian matrix in the difficult global
analysis environment, and the use of parameters defined as components along
appropriately normalized eigenvectors. The result is a set of 2d Eigenvector
Basis parton distributions (where d=16 is the number of parton parameters) from
which the uncertainty on any physical quantity due to the uncertainty in parton
distributions can be calculated. We illustrate the method by applying it to
calculate uncertainties of gluon and quark distribution functions, W boson
rapidity distributions, and the correlation between W and Z production cross
sections.Comment: 30 pages, Latex. Reference added. Normalization of Hessian matrix
changed to HEP standar
Dynamic Spin-Polarized Resonant Tunneling in Magnetic Tunnel Junctions
Precisely engineered tunnel junctions exhibit a long sought effect that
occurs when the energy of the electron is comparable to the potential energy of
the tunneling barrier. The resistance of metal-insulator-metal tunnel junctions
oscillates with an applied voltage when electrons that tunnel directly into the
barrier's conduction band interfere upon reflection at the classical turning
points: the insulator-metal interface, and the dynamic point where the incident
electron energy equals the potential barrier inside the insulator. A model of
tunneling between free electron bands using the exact solution of the
Schroedinger equation for a trapezoidal tunnel barrier qualitatively agrees
with experiment.Comment: 4pgs, 3 fig
Scientific, Technical and Economic Committee for Fisheries. Review of scientific advice for 2012 - Part 2 (STECF-11-09) - Corrigendum
This corrigendum should replace the corresponding sections in the Part 2 of the STECF Review of advice for 2012 (STECF 2011. Review of scientific advice for 2012 – Part 2. Publications Office of the European Union, Luxembourg, EUR 24897 EN, JRC66020)
Panle Discussion: The Impact of U.S. Trade Law Actions on Business Decisions in Taiwan
Transcript of the panel discussion on the impact of United States trade law on business decisions in Taiwan
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