Epoxidized Mesua ferrea L. seed oil-based reactive diluent for BPA epoxy resin and their green nanocomposites

An epoxidized vegetable oil of Mesua ferrea L. seed was prepared and used as a reactive diluent for commercial BPA-based epoxy resin at different compositions for the first time. The prepared epoxidized oil (ENO100) was characterized by determination of physical properties like epoxy equivalent, viscosity, hydroxyl value, saponification value, iodine value, acid value, etc. and FTIR study. The morphology and rheological characteristics of the ENO100 modified commercial epoxy systems have been studied by SEM and rheometer. The performance of poly(amido amine) cured above resin systems have been investigated by the measurement of drying time, tensile strength, elongation at break, adhesive strength, impact resistance, scratch hardness, gloss and chemical resistance studies. The results indicate that the epoxidized oil not only reduces the viscosity of the BPA-based epoxy resin but it also enhances the performance of the cured resin. The performance of this system (50 wt.% dilution) was further enhanced by formation of nanocomposites using ex-situ technique with organically modified nanoclay at different dose levels (1–5 wt.%).The formation of nanocomposites was confirmed by XRD, SEM and FTIR studies. The studies of above performance indicate the enhancement of properties compared to pristine system. As naturally renewable diluent is used in the above studies, so the resultant nanocomposites are green high performance materials with zero VOC.     

Rapid photokilling of gram-negative Escherichia coli bacteria by platinum dispersed titania nanocomposite films

Superior antimicrobial activity of 2 wt.% Pt-dispersed TiO₂ thin film was observed in photokilling Gram-negative Escherichia coli bacteria within 5 min irradiation (640 μW cm⁻², λ > 340 nm) from UV torch than bare TiO₂ film. Severe disruption of cell membrane has occurred over illuminated Pt-TiO₂ catalysts films coated with 100–300 μg powders per 5 cm² areas over sterilized glass slides. The Pt dispersion onto TiO₂ by impregnation–hydrogen reduction always exhibited better photokilling effect than Pt photodeposition, irrespective of Pt–TiO₂ dose and light exposure time. Similar trend in photoactivity difference between two Pt–TiO₂ catalysts is also observed in aqueous slurry because of the unlike surface structure of TiO₂ due to different annealing temperatures, size and nature of Pt particles dispersion onto TiO₂ photocatalysts.     

Superior Functionality by Design: Selective Ozone Sensing Realized by Rationally Constructed High‐Index ZnO Surfaces

A new technique is reported for the transformation of smooth nonpolar ZnO nanowire surfaces to zigzagged high‐index polar surfaces using polycrystalline ZnO thin films deposited by atomic layer deposition (ALD). The c‐axis‐oriented ZnO nanowires with smooth nonpolar surfaces are fabricated using vapor deposition method and subsequently coated by ALD with a ZnO particulate thin film. The synthesized ZnO–ZnO core–shell nanostructures are annealed at 800 °C to transform the smooth ZnO nanowires to zigzagged nanowires with high‐index polar surfaces. Ozone sensing response is compared for all three types of fabricated nanowire morphologies, namely nanowires with smooth surfaces, ZnO–ZnO core–shell nanowires, and zigzagged ZnO nanowires to determine the role of crystallographic surface planes on gas response. While the smooth and core–shell nanowires are largely non‐responsive to varying O₃ concentrations in the experiments, zigzagged nanowires show a significantly higher sensitivity (ppb level) owing to inherent defect‐rich high‐index polar surfaces.     

Use of Ionic Liquid in Fabrication, Characterization, and Processing of Anodic Porous Alumina

Two different ionic liquids have been tested in the electrochemical fabrication of anodic porous alumina in an aqueous solution of oxalic acid. It was found that during galvanostatic anodization of the aluminum at a current density of 200 mA/cm², addition of 0.5% relative volume concentration of 1-butyl-3-methylimidazolium tetrafluoborate resulted in a three-fold increase of the growth rate, as compared to the bare acidic solution with the same acid concentration. This ionic liquid was also used successfully for an assessment of the wettability of the outer surface of the alumina, by means of liquid contact angle measurements. The results have been discussed and interpreted with the aid of atomic force microscopy. The observed wetting property allowed to use the ionic liquid for protection of the pores during a test removal of the oxide barrier layer.     

Conduction based calibration of handmade platinum thin film heat transfer gauges for transient measurements

Heat transfer measurement using thin film gauges (TFG) is the most prevalently used technique for determination of surface heat flux. They are best suited for short duration transient surface temperature measurements and typically used in the applications where convection is a dominant mode of heat transfer such as gas turbine engines, high speed flights etc. However, in few interdisciplinary research areas, there are practical issues and difficulties in exposing the gauges for convection based measurements. These present investigations are aimed at exploring the possibility of using thin film gauges for short duration conduction based transient measurements with pure conduction mode of heat transfer. A simple calibration set-up has been used to supply known heat flux of different magnitudes to the thin film gauges that are fabricated in-house with platinum as sensing element and pyrex as an insulating substrate. Experimentally recorded temperature signals from the gauges are compared with simulated temperature histories obtained through finite element analysis. Convoluted integral of one-dimensional heat conduction equation is used to predict the surface heat flux and compared with input heat loads. The presently developed calibration setup is seen to be very useful for conduction based measurements of thin film gauges.     

Advances in nickel-based cast superalloys

Nickel-based superalloys have served as the most competitive high temperature structural materials under highly stressed and aggressive operating conditions in a variety of applications for more than 60 years. The most demanding among all the applications has been the gas turbine aerofoil castings of modern aero-engines. These turbine parts operate in extremely aggressive environment of high velocity hot combustion gas-air mixture carrying highly corrosive ingredients at high pressure. Gas turbine aerofoil materials should therefore possess adequate resistance to creep, fatigue and aggressive environment. Materials design for such application therefore has been extremely challenging, particularly since the engine designers always aim at higher turbine entry temperature (TET) in order to achieve greater engine thrust and better fuel efficiency. In spite of enormous efforts made in the recent past towards developing ceramics and their composites, Ni-based superalloys continue to be most reliable blade and vane materials offering always the highest TET. This has been possible through better alloy design, improved blade cooling schemes, protective coatings and directional solidification (DS) of either columnar grains or single crystals (SC) along the most favorable 〈001〉 texture. During the last six decades, TET has gone up by about 500K. This article covers recent advances in cast Ni-based superalloys, including our own efforts in this direction. Extensive research at DMRL has led to the development of new generation Ni-based superalloys, designated as DMD-4 and DMS-4 for DS and SC processing, respectively. Simultaneously, expertise has been developed to cast DS and SC components for aero-engines. Technology has also been established for pilot scale production of these components.     

Vacuum-induced Bubble Formation in Liquid-tempered Chocolate

ABSTRACT: Bubble inclusion is one of the fastest growing operations practiced in the food industry. A variety of aerated foods is currently available in supermarkets, and newer products are emerging all the time. This paper aims to combine knowledge on chocolate aeration with studies performed on bubble formation and dispersion characteristics. More specifically, we have investigated bubble formation induced by applying vacuum. Experimental methods to determine gas hold-up (volume fraction of air), bubble section distributions along specific planes, and chocolate rheological properties are presented. This study concludes that decreasing pressures elevate gas hold-up values due to an increase in the number of bubble nuclei being formed and release of a greater volume of dissolved gases. Furthermore, bubbles are observed to be larger at lower pressures for a set amount of gas because the internal pressure needs to be in equilibrium with the surrounding pressures. Temperature-induced changes to the properties of the chocolate have less of an effect on bubble formation. On the other hand, when different fats and emulsifiers are added to a standard chocolate recipe, milk fat was found to increase, significantly, the gas hold-up values and the mean bubble-section diameters. It is hypothesized that this behavior is related to the way milk fats, which contain different fatty acids to cocoa butter, crystallize and influence the setting properties of the final product. It is highlighted that apparent viscosity values at low shear rate, as well as setting behavior, play an important role in terms of bubble formation and entrainment.     

Descriptive epidemiology of thyroid cancer in greater Bombay

Idiopathic varicocele can compromise the spermatogenetic function of the testicle and associate with alterations of the semen quality. The treatment of varicocele stops the progress of testicular damage and improves spermatogenesis and semen parameters. These are the main alternatives to the traditional surgical treatment of varicocele retrograde percutaneous occlusion of the internal spermatic vein using sclerosing agents and embolizing devices (either separately or in combination), microsurgical ligation via inguinal or sub-inguinal approach, laparoscopic ligation and, more recently, antegrade scrotal sclerotherapy. None of these techniques can be considered the "gold standard" therapy. Literature does not point out any significant difference between them, either considering the absence of reflux percentage, or the improvement of semen quality, or the pregnance rate. Therefore cost comparison may be a valid criterion in the choice of treatment for varicocele correction. The total cost of the surgical retroperitoneal unilateral ligation of the internal spermatic vein is 968,805 Lire, while for the bilateral ligation it is 1,118,285 Lire. The costs of sclerotherapy and percutaneous embolization are respectively of 698,750 Lire and 1,708,950 Lire. The combination of the two techniques amounts to 1,918,230 Lire. Laparoscopic bilateral ligation costs 2,437,935 Lire. Antegrade scrotal sclerotherapy costs 191,035 Lire if unilateral, 216,580 Lire if bilateral. After considering these data we can say that antegrade scrotal sclerotherapy is the first choice economically in the treatment of both unilateral and bilateral varicocele.     

Mesua ferrea L. seed oil based highly branched polyester/epoxy blends and their nanocomposites

Mesua ferrea L. seed oil based highly branched polyester and epoxy resins blends were prepared by mechanical mixing at different weight ratios. The best performing blend was used as the matrix for the preparation of nanocomposites with different dose levels of organophilic montmorillonite (OMMT) nanoclay. The prepared nanocomposites were characterized by X‐ray diffraction, scanning electron microscopy, Fourier transform infrared spectroscopy, and transmission electron microscopy. Data resulting from the mechanical and thermal studies of the blends and nanocomposites indicated improvements in the tensile strength and thermal stability to appreciable extents for the nanocomposites with OMMT loading. The nanocomposites were characterized as well‐dispersed, partially exfoliated structures with good interfacial interactions. From the X‐ray diffraction analysis, the absence of d₀₀₁ reflections of the OMMT clay in the cured nanocomposites indicated the development of an exfoliated clay structure, which was confirmed by transmission electron microscopy. The homogeneous morphologies of the pure polyester/epoxy blend and clay hybrid systems were ascertained with scanning electron microscopy. The tensile strength of the 5 wt % clay‐filled blend nanocomposite system was increased by 2.4 times compared to that of the pure blend resin system. The results suggest that the prepared nanocomposites have the potential to be used as active thin films for different applications. © 2011 Wiley Periodicals, Inc. J Appl Polym Sci, 2011     

Adaptive divided difference filtering for simultaneous state and parameter estimation

A novel adaptive version of the divided difference filter (DDF) applicable to non-linear systems with a linear output equation is presented in this work. In order to make the filter robust to modeling errors, upper bounds on the state covariance matrix are derived. The parameters of this upper bound are then estimated using a combination of offline tuning and online optimization with a linear matrix inequality (LMI) constraint, which ensures that the predicted output error covariance is larger than the observed output error covariance. The resulting sub-optimal, high-gain filter is applied to the problem of joint state and parameter estimation. Simulation results demonstrate the superior performance of the proposed filter as compared to the standard DDF.