Transient analysis on surface heated piezoelectric semiconductor plate lying on rigid substrate

Based on the thermo-electro-elastic coupling theory, the mathematical model for a surface heated piezoelectric semiconductor (PS) plate is developed in the time domain. Applying the direct and inverse Laplace transformations to the established model, the mechanical and electrical responses are investigated. The comparison between the analytical solution and the finite element method (FEM) is conducted, which illustrates the validity of the derivation. The calculated results show that the maximum values of the mechanical and electrical fields appear at the heating surface. Importantly, the perturbation carriers tend to concentrate in the zone near the heating surface under the given boundary conditions. It can also be observed that the heating induced elastic wave leads to jumps for the electric potential and perturbation carrier density at the wavefront. When the thermal relaxation time is introduced, all the field quantities become smaller because of the thermal lagging effect. Meanwhile, it can be found that the thermal relaxation time can describe the smooth variation at the jump position. Besides, for a plate with P-N junction, the effect of the interface position on the electrical response is studied. The effects of the initial carrier density on the electrical properties are discussed in detail. The conclusions in this article can be the guidance for the design of PS devices serving in thermal environment.     

The growth and modification of materials via ion–surface processing

A wide variety of gas phase ions with kinetic energies from 1–10⁷ eV increasingly are being used for the growth and modification of state-of-the-art material interfaces. Ions can be used to deposit thin films; expose fresh interfaces by sputtering; grow mixed interface layers from ions, ambient neutrals, and/or surface atoms; modify the phases of interfaces; dope trace elements into interface regions; impart specific chemical functionalities to a surface; toughen materials; and create micron- and nanometer-scale interface structures. Several examples are developed which demonstrate the variety of technologically important interface modification that is possible with gas phase ions. These examples have been selected to demonstrate how the choice of the ion and its kinetic energy controls modification and deposition for several different materials. Examples are drawn from experiments, computer simulations, fundamental research, and active technological applications. Finally, a list of research areas is provided for which ion–surface modification promises considerable scientific and technological advances in the new millennium.     

Physics-based generation of gamma-ray response functions for CdZnTe detectors

A physics-based approach to gamma-ray response-function generation is presented in which the response of CdZnTe detectors is modeled from first principles. Numerical modeling is used to generate response functions needed for spectrum analysis for general detector configurations (e.g., electrode design, detector materials and geometry, and operating conditions). With numerical modeling, requirements for calibration and characterization are significantly reduced. Elements of the physics-based model, including gamma-ray transport, charge carrier drift and diffusion, and circuit response, are presented. Calculated and experimental gamma-ray spectra are compared for a coplanar-grid CdZnTe detector.     

The separation of mixtures of organic liquids by hyperfiltration

Two solid-membrane methods exist for separating mixtures of organic liquids. They are pervaporation, in which the product phase is a vapour, and hyperfiltration in which feed and product phases are both liquid. Technically hyperfiltration is similar to reverse osmosis but, if that term is to be used at all, it should be restricted to dilute solutions of solutes to which the membrane is almost semi-permeable. The polymer membranes which have been found so far to give significant degrees of separation and fluxes with organic liquid mixtures have been crystalline polar polymers with high glass temperatures. The problems of membrane preparation are thus more severe than with almost amorphous, freely soluble polymers such as cellulose acetate.The absorption of liquids from a mixture by a polymer and their permeation in the polymer have received relatively little attention and it is not yet possible to infer the behaviour from that of the polymer towards each liquid alone. Nevertheless a theory of hyperfiltration can be developed based on Henry's and Fick's laws and neglecting any direct coupling of flows. The equations which predict the separation and fluxes are useful in the first place to predict the thermodynamic restraints on any potentially useful separation process. It turns out that relatively large pressures are required, 100 atm or more, and hyperfiltration is better adapted to further purifying a relatively good product than to recovering a small amount of a valuable substance from a large volume of waste.The equations lend themselves to a direct experimental test. An apparatus for doing this has been constructed and two liquid mixtures and membranes have been studied. They are toluene + n-heptane with an asymmetric polyacrylonitrile membrane and methanol + isobutanol with a uniform cellulose membrane. The mixtures were chosen as being thermodynamically close to ideal because this simplifies the interpretation of the data. Their nonideality has been taken fully into account.The results show that the simple theory accounts very well for the observed facts. For the first system the selectivity coefficient was about 2 and for the second, about 15.The mechanism of transport is found to be the normal solution-diffusion mechanism for permeation of organic solvents in polymers. There is some positive frictional coupling between the two liquids as a result of which the improvements in separation to be expected from an increase in the applied pressure are not achieved quantitatively. The increasing absorption of liquid by the membrane as the mole fraction of the preferentially absorbed liquid in the mixture is increased increases its permeability to both components by about     

Muon spin relaxation studies of magnetic-field-induced effects in high-Tc superconductors

Muon spin relaxation measurements in high transverse magnetic fields [FORMULA: SEE TEXT] revealed strong field-induced quasistatic magnetism in the underdoped and Eu-doped (La,Sr)2CuO4 and La1.875Ba0.125CuO4, existing well above Tc and TN. The susceptibility counterpart of Cu spin polarization, derived from the muon spin relaxation rate, exhibits a divergent behavior towards T approximately 25 K. No field-induced magnetism was detected in overdoped La1.81Sr0.19CuO4, optimally doped Bi2212, and Zn-doped YBa2Cu3O7.     

Modeling deoxyribose radicals by neutralization-reionization mass spectrometry. Part 2. Preparation,dissociations, and energetics of 3-hydroxyoxolan-3-yl radical and cation

The title radical (1) is generated in the gas-phase by collisional neutralization of carbonyl-protonated oxolan-3-one. A 1.5% fraction of 1 does not dissociate and is detected following reionization as survivor ions. The major dissociation of 1 (approximately 56%) occurs as loss of the hydroxyl H atom forming oxolan-3-one (2). The competing ring cleavages by O[bond]C-2 and C-4[bond]C-5 bond dissociations combined account for approximately 42% of dissociation and result in the formation of formaldehyde and 2-hydroxyallyl radical. Additional ring-cleavage dissociations of 1 resulting in the formation of C(2)H(3)O and C(2)H(4)O cannot be explained as occurring competitively on the doublet ground (X) electronic state of 1, but are energetically accessible from the A and higher electronic states accessed by vertical electron transfer. Exothermic protonation of 2 also produces 3-oxo-(1H)-oxolanium cation (3(+)) which upon collisional neutralization gives hypervalent 3-oxo-(1H)-oxolanium radical (3). The latter dissociates spontaneously by ring opening and expulsion of hydroxy radical. Experiment and calculations suggest that carbohydrate radicals incorporating the 3-hydroxyoxolan-3-yl motif will prefer ring-cleavage dissociations at low internal energies or upon photoexcitation by absorbing light at approximately 590 and approximately 400 nm.