Physical Principles of Electron Microscopy: An Introduction to TEM, SEM, and AEM

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Scanning and stationary-beam electron microscopes have become an indispensable tool for both research and routine evaluation in materials science, the semiconductor industry, nanotechnology, and the biological and medical sciences. Physical Principles of Electron Microscopy provides an introduction to the theory and current practice of electron microscopy for undergraduate students who want to acquire an appreciation of how basic principles of physics are utilized in an important area of applied science, and for graduate students and technologists who make use of electron microscopes. At the same time, this book will be equally valuable for university teachers and researchers who need a concise supplemental text that deals with the basic principles of microscopy.

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Zeolite Characterization and Catalysis: A Tutorial

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Zeolites have been an important material in catalysis and other applications (adsorbents, detergents) for the last 50 years. While new types of porous materials (ordered mesopores, metal organic frameworks) are now attracting more R&D attention, zeolites are still the most important crystalline industrial catalysts.

Zeolite Characterization and Catalysis: A Tutorial makes available a series of tutorials on zeolite characterization and catalysis. Topics covered include X-ray powder diffraction, infra-red and Raman spectroscopy, Electron microscopy, determination of acid/base properties, the important reactions of C1 building blocks over zeolites as well as zeolite catalysis in chemicals . An important chapter covers computational methods in zeolite science.

Zeolite Characterization and Catalysis: A Tutorial is intended for graduate students, post-docs and experienced scientists entering the fields of synthesis, characterization and catalytic applications of porous materials.

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Asianano, 2002

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This book deals with the broad spectrum of nanoscience and nanotechnology, where interdisciplinary collaboration is essential. Focuses are placed on materials (nanoparticles, dendrimer, CNT), fabrication (LB film, SAM, alternative adsorption, microcontact printing, photofabrication) and characterization (scanning probe microscopy and electron microscopy) on the nanoscale. Emerging applications to nanophotonics and nanobionics are discussed as well.

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Nanomaterials: New Research

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Materials science includes those parts of chemistry and physics that deal with the properties of materials. It encompasses four classes of materials, the study of each of which may be considered a separate field: metals; ceramics; polymers and composites. Materials science is often referred to as materials science and engineering because it has many applications. Industrial applications of materials science include processing techniques (casting, rolling, welding, ion implantation, crystal growth, thin-film deposition, sintering, glassblowing, etc.), analytical techniques (electron microscopy, x-ray diffraction, calorimetry, nuclear microscopy (HEFIB) etc.), materials design, and cost/benefit tradeoffs in industrial production of materials. This book presents new research directions in the very new field of nanomaterials.

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Understanding Carbon Nanotubes: From Basics to Applications

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This volume presents the foundations of carbon nanotube science including the most recent developments and the prospects for technological applications. Each chapter begins with a tutorial introduction to the relevant interdisciplinary topics from physics, chemistry or materials science. These summaries of the essential background knowledge are followed by detailed presentations of specific issues. The latter include: polymorphism of carbon and the microstructure of its phases; synthesis methods and growth mechanisms; structural analysis by electron microscopy; spectroscopic methods; electronic structure; transport; mechanical and surface properties of nanotubes and composites. All readers, be they students or experienced researchers, will come to appreciate how progress in nanotube science is intimately linked to advances in experimental and computational tools.

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