249 research outputs found
Quantification of asbestos and other mineral phase burden in necroscopic human lung tissues with a new method
Background: A large amount of studies on asbestos exposure reconstruction have been so far conducted digesting the lung tissues with appropriate reagents, separating the powder from the digestion liquid by filtration and analysing the residue by optical or electron microscopy. This analytical approach has good sensitivity but is not yet well standardized, the investigated portion is not representative of the bulk sample, the results are often characterized by lack of reproducibility and repeatability. Moreover, the numeric quantification of asbestos requires a time-consuming particle by particle analysis.
Aim: to develop a new method for the complete quantitative characterization of asbestos and other mineral phases in human lung tissue.
Methods: The new method is based on sodium hypochlorite digestion, separation and XRPD analysis. The XRPD approach needs moderate lung tissue amounts (at least 20 g of wet tissue), but allows to conduct a complete quantitative characterization of each crystalline phase in the sample giving bulk-representative results with good reproducibility, accuracy and precision. The detection limit of conventional XRPD was considerably improved by a novel instrumental setting and weight concentrations can be obtained, giving additional information to numeric ones, preferable in clinical and pathogenetic studies but probably not for the exposure reconstruction.
Results: Among the analysed autoptic lung tissues, ten samples belonged to subjects occupationally exposed to asbestos and six were collected from urban area controls. Asbestos phases were detected in none of controls and in 5 of 10 occupationally exposed subjects (those with highest exposure history) indicating that this method is suitable for the reconstruction of medium and high asbestos exposures. It has been furthermore confirmed the mineral association found in previous studies: mainly composed by quartz, talc, clay minerals, micas, Fe-Al-Ti oxides and bio-minerals such Ca-phosphates, carbonates and oxalates
Local structural studies of BaKFeAs using atomic pair distribution function analysis
Systematic local structural studies of BaKFeAs system are
undertaken at room temperature using atomic pair distribution function (PDF)
analysis. The local structure of the BaKFeAs is found to be
well described by the long-range structure extracted from the diffraction
experiments, but with anisotropic atomic vibrations of the constituent atoms
( = ). The crystal unit cell parameters, the
FeAs tetrahedral angle and the pnictogen height above the Fe-plane are seen
to show systematic evolution with K doping, underlining the importance of the
structural changes, in addition to the charge doping, in determining the
properties of BaKFeAs
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The investigation of phase evolution in composite ceramic superconductors using Raman microscopy techniques
Raman microspectroscopy and imaging techniques have been used to investigate key mechanistic features that influence the formation of layered Bi- and Tl-based superconducting phases during the thermal treatment employed to produce BSCCO and TBCCO composite conductors. Seminal information gained from these studies includes the location of lead-rich nonsuperconducting second phases (NSPS) and the identification of the constituent phases in certain NSP agglomerations that tend to resist dissipation as high-Tc phase formation proceeds to completion
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Corrosion of structural materials by lead-based reactor coolants.
Advanced nuclear reactor design has, in recent years, focused increasingly on the use of heavy-liquid-metal coolants, such as lead and lead-bismuth eutectic. Similarly, programs on accelerator-based transmutation systems have also considered the use of such coolants. Russian experience with heavy-metal coolants for nuclear reactors has lent credence to the validity of this approach. Of significant concern is the compatibility of structural materials with these coolants. We have used a thermal convection-based test method to allow exposure of candidate materials to molten lead and lead-bismuth flowing under a temperature gradient. The gradient was deemed essential in evaluating the behavior of the test materials in that should preferential dissolution of components of the test material occur we would expect dissolution in the hotter regions and deposition in the colder regions, thus promoting material transport. Results from the interactions of a Si-rich mild steel alloy, AISI S5, and a ferritic-martensitic stainless steel, HT-9, with the molten lead-bismuth are presented
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Thermodynamic and nonstoichiometric behavior of the lead-doped and lead-free Bi-2212 systems
EMF measurements of oxygen fugacities as a function of stoichiometry were made on pb-doped and Pb-free superconducting ceramics at 700-815 C using oxygen titration. Equations of oxygen partial pressure vs composition and temperature were derived from the EMF measurements. Thermodynamic assessments of the partial molar quantities {Delta}{bar H}(O{sub 2}) and {Delta}{bar S}(O{sub 2}) for Pb-doped Bi- 2212 and Pb-free Bi-2212 indicate that the solid-state decomposition of these Bi cuprates at low oxygen partial pressure can be represented by the diphasic CuO-Cu{sub 2}O system. Comparison of these results with Pb-doped Bi-2223 in powder and silver sheath form is presented
Tests of Micro-Pattern Gaseous Detectors for Active Target Time Projection Chambers in nuclear physics
Active target detection systems, where the gas used as the detection medium is also a target for nuclear reactions, have been used for a wide variety of nuclear physics applications since the eighties. Improvements in Micro-Pattern Gaseous Detectors (MPGDs) and in micro-electronics achieved in the last decade permit the development of a new generation of active targets with higher granularity pad planes that allow spatial and time information to be determined with unprecedented accuracy. A novel active target and time projection chamber (ACTAR TPC), that will be used to study reactions and decays of exotic nuclei at facilities such as SPIRAL2, is presently under development and will be based on MPGD technology. Several MPGDs (Micromegas and Thick GEM) coupled to a 2×2 mm2 pixelated pad plane have been tested and their performances have been determined with different gases over a wide range of pressures. Of particular interest for nuclear physics experiments are the angular and energy resolutions. The angular resolution has been determined to be better than 1° FWHM for short traces of about 4 cm in length and the energy resolution deduced from the particle range was found to be better than 5% for 5.5 MeV α particles. These performances have been compared to Geant4 simulations. These experimental results validate the use of these detectors for several applications in nuclear physics
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Effect of lead content on phase evolution and microstructural development in Ag-clad Bi-2223 composite conductors
A two powder process was used to prepare silver-sheathed monofilamentary Bi{sub 1.8}Pb{sub x}Sr{sub 1.98}Ca{sub 1.97}Cu{sub 3.08}O{sub y} (Bi-2223) tapes with varying lead contents, x, from 0.2 to 0.5. The resulting tapes were subjected to thermomechanical processing and then characterized by x-ray diffraction (XRD), scanning electron microscopy (SEM), and energy dispersive x-ray analysis (EDX). Layered phase texture was accessed using image analysis software on scanned SEM micrographs. Transport currents were measured at 77 K and zero field by the four-probe method. It was found that tapes with low lead content (X = 0.2 and 0.25) showed incomplete conversion to Bi-2223, had small grain size and poor c-axis texture. Tapes having higher lead content (x = 0.4 and 0.5) also showed incomplete conversion and the presence of lead-rich secondary phases. Tapes with lead content x = 0.3 and 0.35 showed complete conversion to Bi-2223, and had the least amount of secondary phases, the best c-axis texture, and the highest transport current (j{sub c}). The carbon content of the precursor powder also had a strong influence on secondary-phase chemistry
Zeros of Orthogonal Polynomials Generated by the Geronimus Perturbation of Measures
Proceedings of: 14th International Conference Computational Science and Its Applications (ICCSA 2014). Guimarães, Portugal, June 30 – July 3, 2014This paper deals with monic orthogonal polynomial sequences
(MOPS in short) generated by a Geronimus canonical spectral transformation
of a positive Borel measure μ, i.e., (x−c)
−1dμ(x)+Nδ(x−c),
for some free parameter N ∈ IR+ and shift c. We analyze the behavior
of the corresponding MOPS. In particular, we obtain such a behavior
when the mass N tends to infinity as well as we characterize the precise
values of N such the smallest (respectively, the largest) zero of these
MOPS is located outside the support of the original measure μ. When
μ is semi-classical, we obtain the ladder operators and the second order
linear differential equation satisfied by the Geronimus perturbed MOPS,
and we also give an electrostatic interpretation of the zero distribution
in terms of a logarithmic potential interaction under the action of an
external field. We analyze such an equilibrium problem when the mass
point of the perturbation c is located outside the support of μ
Pre-transplant psoas muscle density as a ready-to-use and low-cost predictor of patient survival after liver transplant
Background: Sarcopenia, defined as low muscle mass with reduced function, is frequently encountered in cirrhotic patients and is a major predictor of adverse events, including post-liver transplant (LT) outcome. Objectives: This study assessed the impact of sarcopenia using computed tomography (CT-based measurements on post-LT mortality and complications. Methods: From January 2008 to June 2016, 646 adult patients underwent 613 LTs at our institution. We analyzed the postoperative outcome of 287 patients who had pathologically proven cirrhosis on the explanted liver and who had performed a CT examination three months before LT. Psoas muscle density (PMD) was detected for every patient using standard instruments present in the radiological workstation and was related to postoperative survival rates and complications. Statistical analysis was carried out using the appropriate tests. Results: Postoperative mortality was 6.3%. At least one grade III-IV postoperative complication was experienced by 121 patients. Respiratory and infective complications occurred in 30 and 32 patients, respectively. Also, PMD was an independent predictor of postoperative mortality (P = 0.021), respiratory complications (P = 0.015), and infections (P = 0.010). The ROC analysis identified a PMD 43.72 HU as the best cutoff value for predicting 90-day mortality after LT. Conclusions: Psoas muscle density accurately predicted post-LT mortality and complications. Its ease and low-cost determination can allow widespread use of this parameter to improve clinical care and help with the decision to give these patients some priority on the transplant waiting list
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