الصفحة 1
الصفحة 1
Nanoinformatics
Brings out the state of the art on how informatics-based tools are used and expected to be used in nanomaterials research. There has been great progress in the area in which “big-data” generated by experiments or computations are fully utilized to accelerate discovery of new materials, key factors, and design rules. Data-intensive approaches play indispensable roles in advanced materials characterization. "Materials informatics" is the central paradigm in the new trend. "Nanoinformatics" is its essential subset, which focuses on nanostructures of materials such as surfaces, interfaces, dopants, and point defects, playing a critical role in determining materials properties. There have been significant advances in experimental and computational techniques to characterize individual atoms in nanostructures and to gain quantitative information. The collaboration of researchers in materials science and information science is growing actively and is creating a new trend in materials science and engineering.
Materials Syntheses : A Practical Guide
Materials syntheses are generally more complex than syntheses of inorganic or organic compounds, and specific characterization methods play a more important role. Materials synthesis protocols often suffer from unclarities, irreproducibility, lack in detail and lack in standards. The need to change this situation is the main motivation for this book. A number of detailed protocols has been collected, ranging from organic polymers to carbonaceous and ceramic materials, from gels to porous and layered materials and from powders and nanoparticles to films. Preparation methods include intercalation and flux methods, sol-gel processing, templating methods for porous materials, sonochemistry or spray pyrolysis.
BioNanoFluidic MEMS
BioNanoFluidic MEMS explains nanofabrication and nanomaterials synthesis suitable for the development of biosensors. The fundamentals initiate an awareness for engineers and scientists who would like to develop and implement novel biosensors for various applications. In addition, the material covered includes: BioNanoFluidic MEMS connection between the interdisciplinary nature of BioNanoFluidics and MEMS BioNanoFluidics and sensor technology including Micro-Mechanical Sensors and Chemical Sensor Technologies ands-on steps for implementation of biosensor fabrication including a discussion of the clean room lithography process and etching, microsensor systems lamination, PDMS moulding, parylene deposition, and others Interconnection between the interdisciplinary nature of BioNanoFluidics and MEMS BioNanoFluidics and sensor technology including Micro-Mechanical Sensors and Chemical Sensor Technologies
