Structural and Electrical Studies on ZnO-Based Thin Films by Laser Irradiation

The effects of laser irradiation on the structural and electrical properties of ZnO-based thin films were investigated. The XRD pattern shows that the thin films were highly textured along the c-axis and perpendicular to the surface of the substrate. Raman spectra reveal that Bi2O3 segregates mainly at ZnO-ZnO grain boundaries. After laser irradiation processing, the grain size of the film was reduced significantly, and the intrinsic atomic defects of grain boundaries and Bi element segregated at the grain boundary were interacted frequently and formed the composite defects of acceptor state. The nonlinear coefficient increased to 24.31 and the breakdown voltage reduced to 5.34 V

7th EEEIC International Workshop on Environment and Electrical Engineering : Wroclaw - Cottbus, 5 - 11. May 2008

The proposed solution meets the latest trends in world power engineering and has the lowest ecological costs amongst the accessible power engineering solutions. It is also in accordance with the Polish power engineering law, which takes into account the recommendations of the European Economic Commission, the Second Sulphur Protocol and the Framework Convention of the United Nations (concerning the changes of climate)

Modern Surface Engineering Treatments

Surface engineering can be defined as an enabling technology used in a wide range of industrial activities. Surface engineering was founded by detecting surface features which destroy most of pieces, e.g. abrasion, corrosion, fatigue, and disruption; then it was recognized, more than ever, that most technological advancements are constrained with surface requirements. In a wide range of industry (such as gas and oil exploitation, mining, and manufacturing), the surfaces generate an important problem in technological advancement. Passing time shows us new interesting methods in surface engineering. These methods usually apply to enhance the surface properties, e.g. wear rate, fatigue, abrasion, and corrosion resistance. This book collects some of new methods in surface engineering

Ceramic Materials

This is the first book of a series of forthcoming publications on this field by this publisher. The reader can enjoy both a classical printed version on demand for a small charge, as well as the online version free for download. Your citation decides about the acceptance, distribution, and impact of this piece of knowledge. Please enjoy reading and may this book help promote the progress in ceramic development for better life on earth

En route to the industrial applications of ionic liquids for metal oxide production and biomass fractionation: A sustainable avenue to advanced materials

In the context of climate change, it is essential to use renewable materials and to reduce the environmental footprint of industrial processes. This work focuses on the feasibility of implementing a low-cost Ionic Liquid (IL) in a large-scale biorefinery for bioethanol production (the ionoSolv process). The selected feedstock was Eucalyptus red grandis, a fast-growing hardwood. The lignocellulosic biomass was fractionated at laboratory scale, using aqueous N,N,N-trimethylammonium hydrogen sulfate (20 wt% water), at different temperatures and reaction times, to maximize glucose recovery (86%). Experiments under CO2 atmospheres (sub and supercritical) revealed that the ionoSolv process is pressure insensitive. A detailed Techno-Economic Analysis (TEA) for a biorefinery using the ionoSolv pretreatment was performed and compared to one using the acid-catalysed steam explosion pretreatment. With the ionoSolv pretreatment, the composition of the cellulose-rich pulps can be tailored and high-purity lignins can be recovered. The economic performance of both pretreatments are similar. From a sustainability perspective there are trade-offs: the ionoSolv process consumes 25% more energy (with potential for optimization) but consumes less chemicals and produces less waste. These results indicate that this process can be a competitive alternative. During the development of this process, and other IL-based processes, the interaction of ILs (neat and aqueous) with metals was investigated to establish suitable materials of construction. It was observed that the corrosion behaviour of metals exposed to ILs is system dependent. Surprisingly, water can act either as a corrosion inhibitor or promoter. A semi-quantitative classification method for the different corrosion behaviours observed was developed. Some metals exposed to aqueous ILs formed particles, resulting in the inadvertent development of a novel process for metal-based materials at large-scale: Oxidative Ionothermal Synthesis (OIS). A high-level TEA suggests that OIS offers economic and environmentally advantageous production of bulk and advanced metal-based materials, such as zinc oxide.Open Acces