Characterization of CuInS2 thin films prepared by electrodeposition and sulfurization with photoluminescence spectroscopy

Potentiostatic electrodeposition and sulfurization techniques were used to prepare polycrystalline CuInS₂ thin films. X-ray diffraction and photoresponse measurements in a photoelectrochemical cell (PEC) revealed that photoactive polycrystalline CuInS₂ films can be deposited on Ti substrate. Photoluminescence (PL) spectroscopy was used to investigate the prepared thin films and optically characterize them. PL spectra revealed the defect structure of the samples with an acceptor energy level at 109 meV above the valance band and a donor energy level at 71 meV below the conduction band. The CuInS₂ thin films prepared in this investigation are observed to be In-rich material with n-type electrical conductivity.     

Tribological Impact of SiC Encapsulation of Released Polycrystalline Silicon Microstructures

A method for coating released polysilicon microstructures with thin, uniform and conformal coatings of SiC derived from the single source precursor, 1,3-disilabutane (DSB) has been developed. This coating method has been successfully applied to micromechanical test devices which allow evaluation of friction and wear properties of the coating. Here, data on the coefficient of static friction of SiC coatings produced from DSB is presented. Also, a comparative wear study for devices which have been oxidized, treated with an anti-adhesion coating, and SiC coated is shown. Wear is examined by scanning electron microscopy (SEM) on devices which have been cycled repetitively under a nominal load. It is found that the application of a few nanometers-thin SiC coating provides exceptional wear resistance as well as significant reduction in friction on the microscale.     

Sulphidation of electrodeposited cuprous oxide thin films for photovoltaic applications

Electrodeposited cuprous oxide thin films on indium-doped tin oxide (ITO) substrates were sulphided by exposing them to a spray of aqueous solution of sodium sulphide or to a mixture of hydrogen sulphide and nitrogen gases. Both methods produced light darker and darker films having different photovoltaic characteristics in a solar cell structure. The photovoltages produced by the light darker films under AM 1.5 illumination was negative as compared to the positive photovoltages produced by the darker films. Spectral response measurements revealed that most of the light darker films produced positive photovoltages in the shorter wavelengths and negative photovoltages in the longer wavelengths. However, some of the light darker films produced only the negative photovoltage for the entire spectral range and their photovoltaic properties were comparatively better. Darker films resulted in only the positive photovoltages in the entire spectral range. As a result of the sulphidation, the bulk crystal structure of the cuprous oxide thin films was not changed, however, the interfacial characteristics of the solar cell structure were modified.     

Recent progress toward a manufacturable polycrystalline SiC surface micromachining technology

In this paper, we present results of recent research from our laboratory directed toward a manufacturable SiC surface micromachining technology for microelectromechanical systems (MEMS) applications. These include the development of a low-pressure chemical vapor deposition and in situ doping processes for silicon carbide (SiC) films at relatively low temperatures, as well as the development of selective dry etching processes for SiC using nonmetallic masking materials. Doped polycrystalline SiC films are deposited at 800/spl deg/C by using a precursor 1,3-disilabutane and dopant gas NH/sub 3/, with the minimum resistivity of 26 m/spl Omega//spl middot/cm. Dry etching for SiC and its selectivity toward silicon dioxide and silicon nitride masking materials are investigated using SF/sub 6//O/sub 2/, HBr, and HBr/Cl/sub 2/ transformer coupled plasmas. The etch rate, etch selectivity, and etch profile are characterized and compared for each etch chemistry. By combining the LPCVD and dry etching process with conventional microfabrication technologies, a multiuser SiC MEMS process is developed.     

Effect of maturity on some chemical components of cocoa

Immature harvest of cocoa to prevent losses due to pests and pilferage is common in Sri Lanka. The effect of maturity on the levels of some components of the Amelonado variety of cocoa grown in Sri Lanka is reported here. The major problem posed by immature harvest is the loss of fats which has been shown in this study to be of the order of 50% when the crop is harvested 1.5 months early, although the fatty acid composition does not vary significantly during this period. The pulp of immature cocoa pods contains less free sugars and produces less ethanol on yeast fermentation than pulp of mature pods but the methanol content of the distillate is higher in immature pulp. The pectin content of the pod endocarp declines as maturation proceeds.     

Numerical modelling of reinforced concrete columns subject to coupled uplift and shear forces induced by internal explosions

This article investigates the effect of time-variant coupled uplift forces and lateral blast pressures on the vulnerability of reinforced concrete columns when subjected to internal explosions. Detailed examination of archived events has demonstrated that confined blast can induce significant uplift forces on concrete columns carrying predominantly compression loads. These uplift forces can deteriorate the strength of concrete columns leading to destabilisation and a critical loss of structural adequacy. This research employs the applied element method together with high-resolution computational fluid dynamics simulations to model column response due to complex vented and contained internal blast environments. Results from a number of parametric studies highlighted the important effect of uplift forces and blast wave confinement with regard to the overall vulnerability of the column to internal building detonations. This research will be of direct importance to both practitioners and researchers involved with protective design of buildings.     

A SiC MEMS Resonant Strain Sensor for Harsh Environment Applications

In this paper, we present a silicon carbide MEMS resonant strain sensor for harsh environment applications. The sensor is a balanced-mass double-ended tuning fork (BDETF) fabricated from 3C-SiC deposited on a silicon substrate. The SiC was etched in a plasma etch chamber using a silicon oxide mask, achieving a selectivity of 5:1 and etch rate of 2500 Aring/min. The device resonates at atmospheric pressure and operates from room temperature to above 300degC. The device was also subjected to 10 000 g shock (out-of-plane) without damage or shift in resonant frequency. The BDETF exhibits a strain sensitivity of 66 Hz/muepsiv and achieves a strain resolution of 0.11 muepsiv in a bandwidth from 10 to 20 kHz, comparable to state-of-the-art silicon sensors     

Micropatterned nanocrystalline zinc oxide thin films obtained through metal-loaded hydrogels

The paper describes the preparation of micropatterned zinc oxide films through a synthetic route based on the thermal degradation of metal-loaded poly(ethylene glycol)-based hydrogels. This approach requires very simple apparatuses and involves only simple, inexpensive and environmentally friendly chemicals. Highly transparent and crack free nanocrystalline films were obtained through this route. The evolution of the films during the thermal degradation and the influence of synthesis parameters on the film characteristics were investigated by thermal analysis, X-ray grazing incidence diffraction, scanning electron microscopy, atomic force microscopy and micro-Raman. The response toward reducing gasses was tested at different temperatures. Finally, the micropatterning of ZnO films through soft lithography has been characterized.