13,224 research outputs found
Analysis and interpretation of new low-energy Pi-Pi scattering data
The recently published E865 data on charged K_e4 decays and Pi-Pi phases are
reanalyzed to extract values of the two S-wave scattering lengths, of the
subthreshold parameters alpha and beta, of the low-energy constants l3-bar and
l4-bar as well as of the main two-flavour order parameters: and F_pi
in the limit m_u = m_d = 0 taken at the physical value of the strange quark
mass. Our analysis is exclusively based on direct experimental information on
Pi-Pi phases below 800 MeV and on the new solutions of the Roy equations by
Ananthanarayan et al. The result is compared with the theoretical prediction
relating 2 a_0^0 - 5 a_0^2 and the scalar radius of the pion, which was
obtained in two-loop Chiral Perturbation Theory. A discrepancy at the 1-sigma
level is found and commented upon.Comment: Published version, to appear in Eur. Phys. J.
Characteristic Potentials for Mesoscopic Rings Threaded by an Aharonov-Bohm Flux
Electro-static potentials for samples with the topology of a ring and
penetrated by an Aharonov-Bohm flux are discussed. The sensitivity of the
electron-density distribution to small variations in the flux generates an
effective electro-static potential which is itself a periodic function of flux.
We investigate a simple model in which the flux sensitive potential leads to a
persistent current which is enhanced compared to that of a loop of
non-interacting electrons. For sample geometries with contacts the sensitivity
of the electro-static potential to flux leads to a flux-induced capacitance.
This capacitance gives the variation in charge due to an increment in flux. The
flux-induced capacitance is contrasted with the electro-chemical capacitance
which gives the variation in charge due to an increment in an electro-chemical
potential. The discussion is formulated in terms of characteristic functions
which give the variation of the electro-static potential in the interior of the
conductor due to an increment in the external control parameters (flux,
electro-chemical potentials). Paper submitted to the 16th Nordic Semiconductor
Meeting, Laugarvatan, Iceland, June 12-15, 1994. The proceedings will be
published in Physica Scripta.Comment: 23 pages + 4 figures, revtex, IBM-RC1955
Space station integrated wall design and penetration damage control
A methodology was developed to allow a designer to optimize the pressure wall, insulation, and meteoroid/debris shield system of a manned spacecraft for a given spacecraft configuration and threat environment. The threat environment consists of meteoroids and orbital debris, as specified for an arbitrary orbit and expected lifetime. An overall probability of no penetration is calculated, as well as contours of equal threat that take into account spacecraft geometry and orientation. Techniques, tools, and procedures for repairing an impacted and penetrated pressure wall were developed and tested. These techniques are applied from the spacecraft interior and account for the possibility of performing the repair in a vacuum. Hypervelocity impact testing was conducted to: (1) develop and refine appropriate penetration functions, and (2) determine the internal effects of a penetration on personnel and equipment
Space station integrated wall design and penetration damage control
The analysis code BUMPER executes a numerical solution to the problem of calculating the probability of no penetration (PNP) of a spacecraft subject to man-made orbital debris or meteoroid impact. The codes were developed on a DEC VAX 11/780 computer that uses the Virtual Memory System (VMS) operating system, which is written in FORTRAN 77 with no VAX extensions. To help illustrate the steps involved, a single sample analysis is performed. The example used is the space station reference configuration. The finite element model (FEM) of this configuration is relatively complex but demonstrates many BUMPER features. The computer tools and guidelines are described for constructing a FEM for the space station under consideration. The methods used to analyze the sensitivity of PNP to variations in design, are described. Ways are suggested for developing contour plots of the sensitivity study data. Additional BUMPER analysis examples are provided, including FEMs, command inputs, and data outputs. The mathematical theory used as the basis for the code is described, and illustrates the data flow within the analysis
Low-noise slot antenna SIS mixers
We describe quasi-optical SIS mixers operating in the submillimeter band (500-750 GHz) which have very low noise, around 5 h/spl nu//k/sub B/ for the double-sideband receiver noise temperature. The mixers use a twin-slot antenna, Nb/Al-Oxide/Nb tunnel junctions fabricated with optical lithography, a two-junction tuning circuit, and a silicon hyperhemispherical lens with a novel antireflection coating to optimize the optical efficiency. We have flown a submillimeter receiver using these mixers on the Kuiper Airborne Observatory, and have detected a transition of H/sub 2//sup 18/O at 745 GHz. This directly confirms that SIS junctions are capable of low-noise mixing above the gap frequency
Tunneling current characteristics in bilayer quantum Hall systems
Weakly disordered bilayer quantum Hall systems at filling factor show
spontaneous interlayer phase coherence if the layers are sufficiently close
together. We study the collective modes in the system, the current-voltage
characteristics and their evolution with an in-plane magnetic field in the
phase-coherent regime.Comment: 4 pages, 2 figures, grammatical changes, To appear in SCES 2001
proceeding
Spatially Resolved Magnetization in the Bose-Einstein Condensed State of BaCuSi2O6: Evidence for Imperfect Frustration
In order to understand the nature of the two-dimensional Bose-Einstein
condensed (BEC) phase in BaCuSi2O6, we performed detailed 63Cu and 29Si NMR
above the critical magnetic field, Hc1= 23.4 T. The two different alternating
layers present in the system have very different local magnetizations close to
Hc1; one is very weak, and its size and field dependence are highly sensitive
to the nature of inter-layer coupling. Its precise value could only be
determined by "on-site" 63Cu NMR, and the data are fully reproduced by a model
of interacting hard-core bosons in which the perfect frustration associated to
tetragonal symmetry is slightly lifted, leading to the conclusion that the
population of the less populated layers is not fully incoherent but must be
partially condensed
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