A fundamental resource for understanding and developing effective self-assembly and nanotechnology systems Systematically integrating self-assembly, nanoassembly, and nanofabrication into one easy-to-use source, Self-Assembly and Nanotechnology Systems effectively helps students, professors, and researchers comprehend and develop applicable techniques for use in the field. Through case studies, countless examples, clear questions, and general applications, this book provides experiment-oriented techniques for designing, applying, and characterizing self-assembly and nanotechnology systems. Self-Assembly and Nanotechnology Systems includes: * Techniques for identifying assembly building units * Practical assembly methods to focus on when developing nanomaterials, nanostructures, nanoproperties, nanofabricated systems, and nanomechanics * Algorithmic diagrams in each chapter for a general overview * Schematics designed to link assembly principles with actual systems * Hands-on lab activities This informative reference also analyzes the diverse origins and structures of assembly building units, segmental analysis, and selection of assembly principles, methods, characterization techniques, and predictive models. Complementing the author's previous conceptually based book on this topic, Self-Assembly and Nanotechnology Systems is a practical guide that grants practitioners not only the skills to properly analyze assembly building units but also how to work with applications to exercise and develop their knowledge of this rapidly advancing scientific field.
A fundamental resource for understanding and developing effective self-assembly and nanotechnology systems Systematically integrating self-assembly, nanoassembly, and nanofabrication into one easy-to-use source, Self-Assembly and Nanotechnology Systems effectively helps students, professors, and researchers comprehend and develop applicable techniques for use in the field. Through case studies, countless examples, clear questions, and general applications, this book provides experiment-oriented techniques for designing, applying, and characterizing self-assembly and nanotechnology systems. Self-Assembly and Nanotechnology Systems includes: Techniques for identifying assembly building units Practical assembly methods to focus on when developing nanomaterials, nanostructures, nanoproperties, nanofabricated systems, and nanomechanics Algorithmic diagrams in each chapter for a general overview Schematics designed to link assembly principles with actual systems Hands-on lab activities This informative reference also analyzes the diverse origins and structures of assembly building units, segmental analysis, and selection of assembly principles, methods, characterization techniques, and predictive models. Complementing the author's previous conceptually based book on this topic, Self-Assembly and Nanotechnology Systems is a practical guide that grants practitioners not only the skills to properly analyze assembly building units but also how to work with applications to exercise and develop their knowledge of this rapidly advancing scientific field.
Delivers comprehensive coverage of key subjects in self-assembly and nanotechnology, approaching these and related topics with one unified concept. Designed for students and professionals alike, it explores a variety of materials and situations in which the importance of self-assembly nanotechnology is growing tremendously. Provides clear schematic illustrations to represent the mainstream principles behind each topic.
This comprehensive, up-to-date guide to the rehabilitation care of persons with spinal cord injuries and disorders draws on the ever-expanding scientific and clinical evidence base to provide clinicians with all the knowledge needed in order to make optimal management decisions during the acute, subacute, and chronic phases. A wealth of information is presented on the diverse medical consequences and complications encountered in these patients and on the appropriate rehabilitative measures in each circumstance. The coverage encompasses all forms of spinal cord injury and all affected organ systems. Readers will also find chapters on the basics of functional anatomy, neurological classification and evaluation, injuries specifically in children and the elderly, and psychological issues. The book will be an invaluable aid to assessment and medical care for physicians and other professional personnel in multiple specialties, including physiatrists, neurosurgeons, orthopedic surgeons, internists, critical care physicians, urologists, neurologists, psychologists, and social workers.
This book is the first to cover the recently developed MPEG-V standard, explaining the fundamentals of each part of the technology and exploring potential applications. Written by experts in the field who were instrumental in the development of the standard, this book goes beyond the scope of the official standard documentation, describing how to use the technology in a practical context and how to combine it with other information such as audio, video, images, and text. Each chapter follows an easy-to-understand format, first examining how each part of the standard is composed, then covers intended uses and applications for each particular effect. With this book, you will learn how to: Use the MPEG-V standard to develop applications Develop systems for various use cases using MPEG-V Synchronize the virtual world and real world Create and render sensory effects for media Understand and use MPEG-V for the research of new types of media related technology and services The first book on the new MPEG-V standard, which enables interoperability between virtual worlds and the real world Provides the technical foundations for understanding and using MPEG-V for various virtual world, mirrored world, and mixed world use cases Accompanying website features schema files for the standard, with example XML files, source code from the reference software and example applications
This book gives an overview of the existing self-healing nanotextured vascular approaches. It describes the healing agents used in engineering self-healing materials as well as the fundamental physicochemical phenomena accompanying self-healing. This book also addresses the different fabrication methods used to form core–shell nanofiber mats. The fundamental theoretical aspects of fracture mechanics are outlined. A brief theoretical description of cracks in brittle elastic materials is given and the Griffith approach is introduced. The fracture toughness is described, including viscoelastic effects. Critical (catastrophic) and subcritical (fatigue) cracks and their growth are also described theoretically. The adhesion and cohesion energies are introduced as well, and the theory of the blister test for the two limiting cases of stiff and soft materials is developed. In addition, the effect of non-self-healing nanofiber mats on the toughening of ply surfaces in composites is discussed. The book also presents a brief description of the electrochemical theory of corrosion crack growth. All the above-mentioned phenomena are relevant in the context of self-healing materials.
This easy-to-use handbook is designed to assist in the evaluation and management of spinal cord injuries and the diverse related disorders and conditions. Spinal cord injuries can cause abnormalities in all body systems due to dysfunction of the somatic motor and sensory systems and damage to the autonomic nerve system. The latter gives rise to respiratory and cardiac problems, temperature regulation disorders, endocrine system disorders, and many associated metabolic disorders. Other potential consequences of spinal cord injuries include pressure injuries and various disabilities and obstacles, ranging from physical limitations to social embarrassment. This handbook offers extensive guidance on medical management in different scenarios from the acute phase to long-term care, with a particular focus on information of importance for the solution of clinical problems commonly encountered in daily practice. It will be ideal for practitioners in rehabilitation medicine, neurosurgery, orthopedics, neurology, and other relevant specialties that deal with patients with spinal cord injuries.
This book, structured as a collection of questions and answers commonly encountered in the care of individuals with spinal cord injuries, aims to facilitate easy access to clinical and practical information for those involved in their treatment. The author, known for their expertise in spinal cord injuries, has developed this book to offer concise knowledge specifically tailored for clinicians and related healthcare professionals engaged in the care of spinal cord injuries. Unlike his previous works, this book goes beyond the traditional format and incorporates more concise and clinically-oriented questions and answers. Drawing from the author's practical experience and his role in training resident physicians in spinal cord medicine at the University Hospital, the content of this book addresses practical and clinical considerations. To enhance clinical understanding, the book extensively employs figures and tables throughout its comprehensive coverage of various aspects of spinal cord medicine. The author aspires for this book to serve as a valuable clinical companion, providing supplemental practical guidance for daily practice in the field of spinal cord injuries.
Tremendous progress has been made in the geological understanding of the Korean seas with the advances in sophisticated exploration techniques, specifically in the areas of marine geophysics, sedimentology, geochemistry, and palaeoceanography, since Marine Geology of Korean Seas was first published in 1983. This book gives a comprehensive overview of the marine geology of these unique seas, including physiography, sedimentary facies and depositional processes of surface sediments, sequence stratigraphy, geologic structures, and basin evolution. In this edition, new results and interpretations have been incorporated that help to formulate geological models on the evolution of the Korean seas in relation to the adjacent continents.
Grasp the Essential Principles of Membrane Bioreactor ProcessesEvolved from the conventional activated sludge (CAS) process, membrane bioreactor (MBR) processes have become the next-generation solution for municipal and industrial wastewater treatment and recycle. Membrane Bioreactor Processes: Principles and Applications explores nearly all the th
This thesis describes in-depth theoretical efforts to understand the reaction mechanism of graphite and lithium metal as anodes for next-generation rechargeable batteries. The first part deals with Na intercalation chemistry in graphite, whose understanding is crucial for utilizing graphite as an anode for Na-ion batteries. The author demonstrates that Na ion intercalation in graphite is thermodynamically unstable because of the unfavorable Na-graphene interaction. To address this issue, the inclusion of screening moieties, such as solvents, is suggested and proven to enable reversible Na-solvent cointercalation in graphite. Furthermore, the author provides the correlation between the intercalation behavior and the properties of solvents, suggesting a general strategy to tailor the electrochemical intercalation chemistry. The second part addresses the Li dendrite growth issue, which is preventing practical application of Li metal anodes. A continuum mechanics study considering various experimental conditions reveals the origins of irregular growth of Li metal. The findings provide crucial clues for developing effective counter strategies to control the Li metal growth, which will advance the application of high-energy-density Li metal anodes.
During the past several decades, tremendous progress has been made in terahertz (THz) science and technology. There is a continuing need to have terahertz waves ready for practical applications. Terahertz photonic and electronic devices are being readied to be employed in application systems such as communication links, satellite communications, radar, surveillance, hard/soft material heating, biomedical treatment, and biomedical diagnostics. This book focuses on the advances in terahertz source technologies both from photonics and electronics (solid-state and vacuum-state) points of view. Written in a noncomplicated language, the book will be useful for a broad spectrum of readers, including advanced undergraduate- and graduate-level students in electronics and photonics, researchers in various disciplines in physics, chemistry, biology, astronomy, and electrical engineering, system engineers in various industrial sectors, general readers, and those who are interested in the interaction between electromagnetic waves and matters and in the effects of electromagnetic waves on matters.
This book serves as an introductory text for students and engineers with limited knowledge of metamaterials (and elastic waves). This text begins with the most straightforward vibrating systems, such as single and 2-DOF spring-mass systems. It examines the observed phenomena in 2-DOF systems in an unconventional manner to prepare the reader for research on metamaterials. After presenting wave phenomena in an infinitely connected spring-mass system, an elastic bar, a continuous version of an infinite system, is analyzed. This instructional strategy, which progresses from the discrete model to the continuous model, facilitates efficient comprehension of wave and metamaterial concepts. Using continuous and discrete one-dimensional models, bending waves and their manipulation through metamaterials are also discussed. In the latter chapters of this book, advanced readers are introduced to the fundamental wave phenomena in two-dimensional media and wave manipulation using metamaterials, such as mode-converting transmission. As wave phenomena are the fundamental phenomena in vibrating structures, those interested in acoustics and vibration would gain a great deal of knowledge from this book, as the material covered in it offers a very different perspective on oscillatory phenomena than what is typically found in books on acoustics and vibration. Because this book presents a new technique for manipulating waves using metamaterials, engineers and scientists who work with (ultra)sounds and structural vibrations would find it very useful for expanding their knowledge of relevant topics.
This book discusses diverse concepts and notions – and their applications – concerning probability and random variables at the intermediate to advanced level. It explains basic concepts and results in a clearer and more complete manner than the extant literature. In addition to a range of concepts and notions concerning probability and random variables, the coverage includes a number of key advanced concepts in mathematics. Readers will also find unique results on e.g. the explicit general formula of joint moments and the expected values of nonlinear functions for normal random vectors. In addition, interesting applications of the step and impulse functions in discussions on random vectors are presented. Thanks to a wealth of examples and a total of 330 practice problems of varying difficulty, readers will have the opportunity to significantly expand their knowledge and skills. The book is rounded out by an extensive index, allowing readers to quickly and easily find what they are looking for. Given its scope, the book will appeal to all readers with a basic grasp of probability and random variables who are looking to go one step further. It also offers a valuable reference guide for experienced scholars and professionals, helping them review and refine their expertise.
The 2002 Workshop on Frontiers in Electronics was the third in the series of WOFE workshops. Over 70 leading experts from academia, industry, and government agencies reported on the most recent developments in their fields and exchanged views on future trends and directions of the electronics and photonics industry. The issues they addressed ranged from system-on-chip to DNA doping, from ultrathin SOI to electrotextiles, from photonics integration on the ULSI platform to wide band gap semiconductor devices and solid state lighting. The rapid pace of electronic technology evolution compels a merger of different technical areas, and WOFE-02 provided a unique opportunity for cross-fertilization of the emerging fields of microelectronics, photonics, and nanoelectronics. The workshop was informal and stimulated provocative views, visionary outlooks, and discussions on controversial issues. Contents: Optical Wave Propagation in Periodic Structures (A Yariv & S Mookherjea); MEMS Technology for Advanced Telecommunication Applications (H-G Lee et al.); Low Temperature Physics at Room Temperature in Water: Charge Inversion in Chemical and Biological Systems (A Yu Grosberg et al.); Materials for Strained Silicon Devices (P M Mooney); System-on-Chip Integration (R R Doering); Nanoelectronics: Some Current Aspects and Prospects (R Hull et al.); Electrotextiles (E Ethridge & D Urban); System Impact of Silicon Carbide Power Devices (B Ozpineci et al.); Hot-Phonon Limited Electron Energy Relaxation in AIN/GaN (A Matulionis et al.); Polar-Optical Phonon Enhancement of Harmonic Generation in Schottky Diodes (B Gelmont et al.); Environmental Sensing of Chemical and Biological Warfare Agents in the THz Region (A C Samuels et al.); Thermal Management in Optoelectronics (D K Johnstone); Spectral Response Measurements of Short Wave Infrared Detectors (SWIR) (T F Refaat et al.); Full-Chip Power-Supply Noise: The Effect of On-Chip Power-Rail Inductance (C W Fok & D L Pulfrey); Quantum Dot Superlattices in a Constant Electric Field: Localization and Bloch Oscillations (R A Suris & I A Dmitriev); and other papers. Readership: Scientists, engineers and graduate students working in the area of microelectronics, semiconductor materials and devices.
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