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Understanding Carbon Nanotubes : From Basics to Applications

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.

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Synthesis, Properties and Applications of Ultrananocrystalline Diamond ; Proceedings of the NATO ARW on Synthesis, Properties and Applications of Ultrananocrystalline Diamond, St. Petersburg, Russia, from 7 to 10 June 2004.

There are two forms of UNCD, dispersed particles and films. The two communities of researchers working on these two forms of UNCD have hitherto lacked a common forum in which to explore areas of scientific and technological overlap. As a consequence, the two fields have up to now developed independently of each other. The time had clearly come to remedy this situation in order to be able to take full advantage of the enormous potential for societal benefits to be derived from exploiting the synergistic relationships between UNCD dispersed particulates and UNCD films. The NATO sponsored ARW therefore occurred in a very timely manner and was successful in beginning the desired dialogue, a precondition for making progress toward the above stated goal. The discovery of UNCD completes a triadof nanostructured carbonswhich includes fullerenes and nanotubes.

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Surface Engineered Surgical Tools and Medical Devices

Surface Engineered Surgical Tools and Medical Devices presents the latest information and techniques in the emerging field of surface engineered biomedical devices and surgical tools, and analyzes the interaction between nanotechnology, nanomaterials, and tools for surgical applications. Chapters of the book describe developments in coatings for heart valves, stents, hip and knee joints, cardiovascular devices, orthodontic applications, and regenerative materials such as bone substitutes. Chapters are also dedicated to the performance of surgical tools and dental tools and describe how nanostructured surfaces can be created for the purposes of improving cell adhesion between medical devices and the human body.

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Supramolecular Chemistry - Fundamentals and Applications : Advanced Textbook

The book conveys the relevance and fascination of the fast-growing field of supramolecular chemistry to advanced undergraduate students, and provides an overview of it to young scientists and engineers. Readers will find that supramolecular chemistry is associated with many attractive disciplines of chemistry, including molecular recognition, molecular topology, self-organization, ultrathin films, molecular devices and biomolecular systems. Supramolecular chemistry is still a very young field, and so it is difficult to predict its future, but it has already secured a firm position in the chemical sciences. For example, biotechnology and nanotechnology are expected to lead to technological revolutions in the near future that will dramatically affect our lifestyles and economies. Supramolecular chemistry is an indispensable tool in these technologies. 

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Spectroscopy of emerging materials ; Proceedings of the NATO ARW on frontiers in spectroscopy of emergent materials : Recent advances toward new technologies, Sudak, Crimea, Ukraine, from 14 to 18 September 2003.

A comprehensive discussion of the key role of modern spectroscopic investigations in interdisciplinary materials science and engineering, covering emerging materials that are either absolutely novel or well-known materials with recently discovered, exciting properties. The types of spectroscopy discussed include optical, electronic and magnetic, UV-visible absorption, Rayleigh scattering, photoluminescence, vibrational, magnetic resonance, electron energy loss, EXAFS, XANES, optical tomography, time-resolved spectroscopy, and point contact spectroscopy. The materials studied are highly topical, with a focus on carbon and silicon nanomaterials including nanotubes, fullerenes, nanoclusters, metallic superconducting phases, molecular materials, magnetic and charge-stripe oxides, and biomaterials. Theoretical treatments are presented of molecular vibrational dynamics, vibration-induced decay of electronic excited states, nanoscale spin-orbit coupling in 2D Si-based structures, and the growth of semiconductor clusters.

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Self-Assembled Nanomaterials II : Nanotubes

This series presents reviews of the present and future trends in polymer and biopolymer science including chemistry, physical chemistry, physics and materials science. It is addressed to all scientists at universities and in industry who wish to keep abreast of advances in the topics covered. A variety of nanofibers with well defined morphologies and dimensions are discussed in terms of self-assembly of molecular and polymer building blocks in bulk solution or confined geometry like nanopores.

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Scanning Probe Microscopy : Electrical and Electromechanical Phenomena at the Nanoscale

Scanning Probe Microscopy brings up to date a constantly growing knowledge base of electrical and electromechanical characterization at the nanoscale. This comprehensive, two-volume set presents practical and theoretical issues of advanced scanning probe microscopy (SPM) techniques ranging from fundamental physical studies to device characterization, failure analysis, and nanofabrication. Volume 1 focuses on the technical aspects of SPM methods ranging from scanning tunneling potentiometry to electrochemical SPM, and addresses the fundamental physical phenomena underlying the SPM imaging mechanism. Volume 2 concentrates on the practical aspects of SPM characterization of a wide range of materials, including semiconductors, ferroelectrics, dielectrics, polymers, carbon nanotubes, and biomolecules, as well as on SPM-based approaches to nanofabrication and nanolithography.

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Scanning probe microscopy : Characterization, nanofabrication and device application of functional materials ; Proceedings of the NATO Advanced Study Institute on scanning probe microscopy : Characterization, nanofabrication and device application of functional materials, Algarve, Portugal, 1 - 13 October 2002

Scanning Probe Microscopy (SPM) is opening new opportunities to measure semiconductor electronic properties with unprecedented spatial resolution. SPM is being successfully applied for nanoscale characterization of ferroelectric thin films. In the area of functional molecular materials it is being used as a probe to contact molecular structures in order to characterize their electrical properties, as a manipulator to assemble nanoparticles and nanotubes into simple devices, and as a tool to pattern molecular nanostructures. This book provides in-depth information on new and emerging applications of SPM to the field of materials science, namely in the areas of characterisation, device application and nanofabrication of functional materials. Starting with the general properties of functional materials the authors present an updated overview of the fundamentals of Scanning Probe Techniques and the application of SPM techniques to the characterization of specified functional materials such as piezoelectric and ferroelectric and to the fabrication of some nano electronic devices. ...

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Scanning Microscopy for Nanotechnology : Techniques and Applications

Scanning electron microscopy (SEM) can be exploited not only for nanomaterials characterization but also integrated with new technologies for in-situ nanomaterials engineering and manipulation. Scanning Microscopy for Nanotechnology addresses the rapid development of these techniques for nanotechnology, in both technique and application chapters by leading practitioners. The book covers topics including nanomaterials imaging, X-ray microanalysis, high-resolution SEM, low kV SEM, cryo-SEM, as well as new techniques such as electron back scatter diffraction (EBSD) and scanning transmission electron microscopy (STEM). Fabrication techniques integrated with SEM, such as e-beam nanolithography, nanomanipulation, and focused ion beam nanofabrication, are major new dimensions for SEM application.

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Physics of Zero- and One-Dimensional Nanoscopic Systems

In recent years submicron and nanoscale systems have featured strongly on the research agenda due to the technological progress and new physics that have emerged from studies of ultra-small systems. A fundamental understanding of basic physical phenomena on the mesoscopic and nanoscopic scales is required to exploit the technological potential offered by these exotic materials. The present book contains review-like chapters by some of the leading experts in the field, covering topics such as the Kondo effect, electron transport, disorder and quantum coherence with electron-electron interaction, persistent current, thermoelectric phenomena, etc. in quantum dots, quantum wires, carbon nanotubes and more. This book will be valuable to researchers and students in condensed matter physics.

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Physical Properties of Polymers Handbook

This handbook offers concise information on the properties of polymeric materials, particularly those most relevant to the areas of physical chemistry and chemical physics. In the second edition of Physical Properties of Polymers Handbook, each chapter has been extensively updated and revised. The number of  chapters have increased from 52 to 63 to include novel polymeric structures, specifically rotaxanes and related materials, self-assembly materials, foldamer supramolecular structures, tribology, mechanical properties of single molecules, and dendrimers, as well as reinforcing phases in polymers, including carbon black, silica, clays and other layered fillers, POSS, carbon nanotubes, and reinforcement theory.

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Photon-based Nanoscience and Nanobiotechnology

Light has always played a significant role in the synthesis of materials and formation of small-scale solid structures. The invention of holographic and phase mask projection has enabled engineers to fabricate devices with characteristic features much smaller than the wavelength of the light used for processing. A further reduction of device dimensions has been achieved by implementing the processes that rely strongly on the non-linear effects of light-matter interaction. The intention of this book was to provide the Reader, primarily graduate students and young researchers in materials engineering, bio(chem)physics, medical physics and biophysics, with a set of articles reviewing state-of-the art research and recent advancements in the field of photon-matter interaction for micro/nanomaterials synthesis and manipulation of properties of biological and inorganic materials at the atomic level.

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One-Dimensional Nanostructures

One-dimensional (1D) nanostructures, including nanowires, nanotubes and quantum wires, have been regarded as the most promising building blocks for nanoscale electronic and optoelectronic devices. Worldwide efforts in both the theory and the experimental investigation of growth, characterization and applications of 1D nanostructures have resulted in a mature, multidisciplinary field. In this book, a wealth of state-of-the-art information offers the opportunity to uncover the underlying science from diverse perspectives. Leading researchers elucidate the synthesis and properties of 1D nanostructures for various morphologies and compositions (semiconductor, metal, carbon, etc.) as well as their considerable impact on spintronics, information storage, and the design of field-effect transistors.

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New Carbon Based Materials for Electrochemical Energy Storage Systems : Batteries, Supercapacitors and Fuel Cells

This NATO-ARW volume contains a diverse collection of papers addressing the role of carbon in some key electrochemical systems, both conventional and emerging. These papers discuss the latest issues associated with development, synthesis, characterization and use of new advanced carbonaceous materials for electrochemical energy storage. Such systems include: metal-air primary and rechargeable batteries, fuel cells, supercapacitors, cathodes and anodes of lithium-ion and lithium polymer rechargeable batteries, as well as nanocarbon materials of the future.

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Nanotechnology ¿ Toxicological Issues and Environmental Safety and Environmental Safety

Nanotechnology is one of the fastest growing technological fields of the 21st century. Nanotechnologies will impact numerous industries, including daily consumer products, health care, energy, and transportation. However, the success of the emerging nanotechnology applications will depend on dynamic development of nanomaterial toxicology, risk and exposure assessment. Little is known about the potential adverse health and ecological effects of exposure to engineered nanomaterials, the main components of many nanotechnologies. Concerns are coming from the initial toxicological studies as well as the research and epidemiological reports on ultrafine particle toxicity. This book provides a summary of the state-of-art knowledge on nanomaterials and nanoparticles – toxicological issues; risk assessment and control measures.

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Nanostructures : Fabrication and Analysis

The main theme of this book is the exploration the underlying physical laws that permit the fabrication of nanometer-scale structures. As researchers attempt to fabricate nanometer-scale structures which do not exist per se, they must still employ the natural laws to fabricate them through processes such as self-assembly. So it turns out that our techniques for fabrication of nanometer-scale structures are not artificial but actually rely on the natural laws. We even find that nanometer-scale structures, e.g. fullerenes, are fabricated in nature beneath the surface of the Earth. This fact may be called the ubiquity of the nanometer-scale structures. The topics presented in the book include: scanning probe-related and near-field techniques, nanolithography, self assembling and design of novel nanostructures, as well as new nanodevices and their application.

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Nanoscale Phenomena : Basic Science to Device Applications

Nanotechnology is the result of the continuing technological trend toward device miniaturization and the characterization, manipulation, and fine control of structure and function at diminishing length scales. A large class of nanoscale materials can be stable even though they are far from the lowest-energy thermodynamic state, and many possess novel properties unattainable in bulk. These trends are supported by the increasing sophistication of characterization and fabrication tools such as the scanning tunneling microscope and the transmission electron microscope, which allow the resolution and manipulation of single atoms and molecules.

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Nanomechanics of Materials and Structures

This book is derived from the proceedings of the International Workshop on Nanomechanics held at Asilomar Conference Grounds in Pacific Grove, California on July 14-17, 2004. The main objective was to convene leading researchers in the nanotechnology community to assess the current state-of-the-art and disseminate recent progress, critical issues, barriers to applications, and directions for future research in nanomechanics.

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Molecular Materials with Specific Interactions - Modeling and Design

One of the first requirements to initiate the molecular modeling of molecular materials is an accurate and realistic description of the electronic structure, intermolecular interactions and chemical reactions at microscopic and macroscopic scale. Therefore the first four chapters contain an extensive introduction into the latest theories of intermolecular interactions, functional density techniques, microscopic and mezoscopic modeling techniques as well as first-principle molecular dynamics.In the following chapters, techniques bridging microscopic and mezoscopic modeling scales are presented. The authors then illustrate various successful applications of molecular design of new materials, drugs, biocatalysts, etc. before presenting challenging topics in molecular materials design.

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Molecular Electronics Materials, Devices and Applications

another goal of Molecular Electronics Materials, Devices and Applications is also to promote a practical approach. As a starting point for future developments, a pragmatic methodology for VHDL-AMS device modelling and circuit design based on experimental data is then proposed. It includes an original fault tolerant memory architecture based on molecular electronics.

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