Nanotechnology & MEMS
Already, scientists have constructed prototypes for circuit boards built of millions of precisely arranged atoms. The advent of this kind of atomic precision promises to change the way we make things—cleanly, inexpensively, and on a global scale. It allows us to imagine a world where solar arrays cost no more than cardboard and aluminum foil, and laptops cost about the same.
A provocative tour of cutting edge science and its implications by the field's founder and master, Radical Abundance offers a mind-expanding vision of a world hurtling toward an unexpected future.
It explains micro-engineering issues (design, systems, materials, market and industrial development), technologies, facilities, organization, competitiveness, and innovation with an analysis of future potential.
The machining, forming, and joining of miniature / micro-products are all covered in depth, covering: grinding/milling, laser applications, and photo chemical etching; embossing (hot & UV), injection molding and forming (bulk, sheet, hydro, laser); mechanical assembly, laser joining, soldering, and packaging.
• Presents case studies, material and design considerations, working principles, process configurations, and information on tools, equipment, parameters and control
• Explains the many facets of recently emerging additive / hybrid technologies and systems, incl: photo-electric-forming, liga, surface treatment, and thin film fabrication
• Outlines system engineering issues pertaining to handling, metrology, testing, integration & software
• Explains widely used micro parts in bio / medical industry, information technology and automotive engineering.
• Covers technologies in high demand, such as: micro-mechanical-cutting, lasermachining, micro-forming, micro-EDM, micro-joining, photo-chemical-etching, photo-electro-forming, and micro-packaging
The world of nanotechnology is ever changing and evolving; this fun and friendly guide demystifies the topic for anyone interested in how molecule-sized machines and processes affect our everyday lives. The authors begin with explaining the background of nanotechnology and then examine industries that are affected by this technology. Aiming to educate and simultaneously dispel common myths, the book explores the many nanotechnology-enabled consumer products available on the market today, ranging from socks to face lotion to jet skis to floor cleaners, to name a few.Serves as a fun and friendly introduction to the fascinating topic of nanotechnology Discusses the various issues involving nanotechnology in the areas of environment, medicine, defense, and others Provides real-world examples of everyday nanotechnology use such as floor cleaners, flash memory drives, face lotion, computer processors, and more
Written in the accessible, humorous For Dummies style, Nanotechnology For Dummies, 2nd Edition provides an easy-to-understand overview of nanotechnology and its real-world implementation.
Winner of a CHOICE Outstanding Academic Book Award 2011
"... takes the revolutionary concepts and techniques that have traditionally been fodder for graduate study and makes them accessible for all. ... outstanding introduction to the broad field of nanotechnology provides a solid foundation for further study. ... Highly recommended."
—N.M. Fahrenkopf, University at Albany, CHOICE Magazine 2011
Give your students the thorough grounding they need in nanotechnology. A rigorous yet accessible treatment of one of the world’s fastest growing fields, Nanotechnology: Understanding Small Systems, Third Edition provides an accessible introduction without sacrificing rigorous scientific details. This approach makes the subject matter accessible to students from a variety of disciplines. Building on the foundation set by the first two bestselling editions, this third edition maintains the features that made previous editions popular with students and professors alike.
See What’s New in the Third Edition:
Updated coverage of the eight main facets of nanotechnology Expanded treatment of health/environmental ramifications of nanomaterials Comparison of macroscale systems to those at the nanoscale, showing how scale phenomena affects behavior New chapter on nanomedicine New problems, examples, and an exhaustive nanotech glossary
Filled with real-world examples and original illustrations, the presentation makes the material fun and engaging. The systems-based approach gives students the tools to create systems with unique functions and characteristics. Fitting neatly between popular science books and high-level treatises, the book works from the ground up to provide a gateway into an exciting and rapidly evolving area of science.
The editors have built Advances in Molecular Nanotechnology Research and Application: 2011 Edition on the vast information databases of ScholarlyNews.™ You can expect the information about Molecular Nanotechnology in this eBook to be deeper than what you can access anywhere else, as well as consistently reliable, authoritative, informed, and relevant. The content of Advances in Molecular Nanotechnology Research and Application: 2011 Edition has been produced by the world’s leading scientists, engineers, analysts, research institutions, and companies. All of the content is from peer-reviewed sources, and all of it is written, assembled, and edited by the editors at ScholarlyEditions™ and available exclusively from us. You now have a source you can cite with authority, confidence, and credibility.
CMOS Processors and Memories is divided into two parts: processors and memories. In the first part we start with high performance, low power processor design, followed by a chapter on multi-core processing. They both represent state-of-the-art concepts in current computing industry. The third chapter deals with asynchronous design that still carries lots of promise for future computing needs. At the end we present a “hardware design space exploration” methodology for implementing and analyzing the hardware for the Bayesian inference framework. This particular methodology involves: analyzing the computational cost and exploring candidate hardware components, proposing various custom architectures using both traditional CMOS and hybrid nanotechnology CMOL. The first part concludes with hybrid CMOS-Nano architectures.
The second, memory part covers state-of-the-art SRAM, DRAM, and flash memories as well as emerging device concepts. Semiconductor memory is a good example of the full custom design that applies various analog and logic circuits to utilize the memory cell’s device physics. Critical physical effects that include tunneling, hot electron injection, charge trapping (Flash memory) are discussed in detail. Emerging memories like FRAM, PRAM and ReRAM that depend on magnetization, electron spin alignment, ferroelectric effect, built-in potential well, quantum effects, and thermal melting are also described.
CMOS Processors and Memories is a must for anyone serious about circuit design for future computing technologies. The book is written by top notch international experts in industry and academia. It can be used in graduate course curriculum.
What the future will hold for us when it comes to the newest inventions in Physics, Computing and Science?
In the last 20 years, computers really changed the way we live our lives.
Now, it is time to look into the future and predict what's coming based on what science knows.
Let's get into the journey of what might be considered as "science fiction" today, but really a step closer to a new and better future (the reality of tomorrow).
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Nanotechnology: Ethics and Society provides a conceptually clear and straightforward ethical framework, in which pragmatic questions can be raised regarding the impact of nano-related technologies. The book focuses on general issues related to nanotechnology in nanomaterials and manufacturing as well as impacts on the marketplace and workforce. After an overview of the nanotechnology revolution, the text illustrates key concepts in the assessment model and then applies this model to a case study related to human enhancement technologies. It also offers an ethical agenda for addressing the challenges of nanotechnology.
Nanotechnology promises to be the next great technological revolution. This important volume provides a framework for deciding how best to take advantage of nanotechnology opportunities while also minimizing the harm of negative effects.
The material is presented in the simplest possible way, including a few mathematical equations, but not mathematical derivations. It also outlines as simply as possible the major contributions to modern technology of physics-based nanophysical devices, such as the atomic clock, global positioning systems, and magnetic resonance imaging. As a result, readers are able to establish a connection between nanotechnology and day-to-day applications, as well as with advances in information technology based on fast computers, the internet, dense data storage, Google searches, and new concepts for renewable energy harvesting.
Also of interest to professionals working in law, finance, or teaching who wish to understand nanotechnology in a broad context, and as general reading for electrical, chemical and computer engineers, materials scientists, applied physicists and mathematicians, as well as for students of these disciplines.
A ciência e tecnologia estão cada vez mais fazendo parte do nosso cotidiano. Nanopartículas tornarão os plásticos e vidros mais resistentes e funcionais. Diagnósticos clínicos poderão ser feitos com um pequeno cartão. Os medicamentos serão programados para atingirem os seus alvos. As janelas serão inteligentes, terão sua tonalidade ajustável e dispensarão produtos de limpeza. Células a combustível moverão silenciosamente os nossos carros. Isto não é um sonho. É a revolução que começa agora com a era da nanotecnologia.
Este é o primeiro livro da série Inventando o Futuro, que dá um panorama contemporâneo dos avanços e dos desafios a serem enfrentados em diversas áreas da Ciência e da Tecnologia modernas. Os livros desta série mostram como é fascinante o mundo da ciência que supera a própria imaginação.
MEMs Reliability, focuses on the reliability and manufacturability of MEMS at a fundamental level by addressing process development and characterization, material property characterization, failure mechanisms and physics of failure (POF), design strategies for improving yield, design for reliability (DFR), packaging and testing.
Topics covered include:
Patterning of biomimetic substrates with AFM lithography, primarily focusing on DPN Nanotemplating polymer melts Nanotechnology-based approaches in the treatment of injuries to tendons and ligaments Progress in the use of electrospinning processing techniques for fabricating nanofiber scaffolds for neural applications Nanotopography techniques for tissue-engineered scaffolds and the effects of nanotopography on cells and tissues Vertically aligned TiO2 nanotube surface structuring for optimization of Ti implants utilizing nanotechnology Applications originating from the harmony of nanotechnology to biological systems, especially for the regeneration in the nervous system Current understanding of the mechanisms by which cells sense nano-scale structure at the molecular level and how this understanding can be useful in developing novel antifouling materials
While there are books available on tissue engineering and nanotechnology and others about regenerative medicine, most do not comprehensively cover applications of nanotechnology to both these areas. Focusing chiefly on drug delivery, tissue engineering, and regenerative medicine, the book uses an application-based approach to relate laboratory-based research to the development of technologies that can be readily adaptable to an industrial environment.
Separated into five chapters, the book begins by addressing research methodology, how to design successful experiments, and ethics in science. It also provides practical information on data collection and analysis, keeping a laboratory notebook, and writing laboratory reports. With each section written by a distinguished researcher, chapter 2 reviews common techniques for the characterization and analysis of colloidal structures, including surface tension measurements, viscosity and rheological measurements, electrokinetic methods, scattering and diffraction techniques, and microscopy.
Chapters 3–5 provide 19 experiments, each including the purpose of the experiment, background information, pre-laboratory questions, step-by-step procedures, and post-laboratory questions. Chapter 3 contains experiments about colloids and surfaces, such as sedimentation, exploration of wetting phenomena, foam stability, and preparation of miniemulsions. Chapter 4 covers various techniques for the preparation of nanoparticles, including silver, magnetic, and silica nanoparticles. Chapter 5 demonstrates daily-life applications of colloid science, describing the preparation of food colloids, body wash, and body cream.
Patrick McCray traces how these visioneers blended countercultural ideals with hard science, entrepreneurship, libertarianism, and unbridled optimism about the future. He shows how they built networks that communicated their ideas to writers, politicians, and corporate leaders. But the visioneers were not immune to failure--or to the lures of profit, celebrity, and hype. O'Neill and Drexler faced difficulty funding their work and overcoming colleagues' skepticism, and saw their ideas co-opted and transformed by Timothy Leary, the scriptwriters of Star Trek, and many others. Ultimately, both men struggled to overcome stigma and ostracism as they tried to unshackle their visioneering from pejorative labels like "fringe" and "pseudoscience.?
The Visioneers provides a balanced look at the successes and pitfalls they encountered. The book exposes the dangers of promotion--oversimplification, misuse, and misunderstanding--that can plague exploratory science. But above all, it highlights the importance of radical new ideas that inspire us to support cutting-edge research into tomorrow's technologies.
Some images inside the book are unavailable due to digital copyright restrictions.
The low-power low-voltage Sigma-Delta modulator design at the circuit level is introduced. A design example is presented in this book. This design is the first published Sigma-Delta design in a 90-nm CMOS technology and reaches a very high figure-of-merit.
At the system level, a novel systematic study on the full feedforward Sigma-Delta topology is presented in this book. As a design example, a fourth-order single-loop full feedforward Sigma-Delta modulator design in a 130-nm pure digital CMOS technology is presented. This design is the first design using the full feedforward Sigma-Delta topology and reaches the highest conversion speed among all the 1-V Sigma-Delta modulators to date.
Nanotechnology: Basic Science and Emerging Technologies bridges the gap between detailed technical publications that are beyond the grasp of nonspecialists and popular science books, which may be more science fiction than fact. It provides a fascinating, scientifically sound treatment, accessible to engineers and scientists outside the field and even to students at the undergraduate level. After a basic introduction to the field, the authors explore topics that include molecular nanotechnology, nanomaterials and nanopowders, nanoelectronics, optics and photonics, and nanobiometrics. The book concludes with a look at some cutting-edge applications and prophecies for the future.
Nanoscience will bring to the world technologies that today we can only imagine and others of which we have not yet dreamt. This book lays the groundwork for that future by introducing the subject to those outside the field, sparking the imaginations of tomorrow's scientists, and challenging them all to participate in the advances that will bring nanotechnology's potential to fruition.
Optimize your use of free resources from the National Science Foundation
The first book of its kind, Nanoscience Education, Workforce Training, and K–12 Resources promotes nano-awareness in both the public and private sectors, presenting an overview of the current obstacles that must be overcome within the complex U.S. educational system before any reform is possible. It’s a race against time—and other countries—and the fear is that U.S. students could lag behind for decades, with ineffective teaching and learning methods handicapping their ability to compete globally.
Focusing on the application of new knowledge, this concise and highly readable book explores the transdisciplinary nature of nanoscience and its societal impact, also addressing workforce training and risk management. Illustrating the historical perspective of the complexity of K–12 education communities, it defines nanotechnology and evaluates pertinent global and national landscapes, presenting examples of successful change within them.
This book is composed of four sections:
Foundations—addresses the national educational matrix, exploring the scientific and social implications associated with the delay in adopting nanoscience education in public schools
Teaching Nanotechnology—discusses the critical process of teaching K–12 students the skills to understand and evaluate emerging technologies they will encounter
Nanoscience Resources and Programs—provides a wide overview of the resources offered by funded outreach programs from universities with nanoscience centers
Framework Applied—analyzes the structure of national government programs and skill level recommendations for nanoeducation from the National Nanotechnology Initiatives
This book offers plans of action and links to sustainable (largely free) development tools to help K–12 students acquire the skills to understand and evaluate emerging technologies. Promoting a holistic teaching approach that encompasses all aspects of science, the authors strive to help readers implement change so that decisions about resources and learning are no longer made "from the top down" by policymakers, but rather "from the bottom up" by teachers, parents, and students at the local level.
Akhlesh Lakhtakia, one of the contributors to this volume, was recently featured on CNN in a discussion on solar energy.
The book takes the reader from the fundamentals of wave propagation in nanotubes to more advanced topics such as rotating nanotubes, coupled nanotubes, and nanotubes with magnetic field and surface effects. The first few chapters cover the basics of wave propagation, different modeling schemes for nanostructures and introduce non-local elasticity theories, which form the building blocks for understanding the material provided in later chapters. A number of interesting examples are provided to illustrate the important features of wave behavior in these low dimensional structures.
In this revised method four fundamental disciplines are combined: i) thermodynamics of materials ii) reaction kinetics iii) theory of microstructures and iv) stress and strain analysis. The advantages of the method are illustrated in Interfacial Compatibility in Microelectronics which includes:
•solutions to several common reliability issues in microsystem technology,
•methods to understand and predict failure mechanisms at interfaces between dissimilar materials and
•an approach to DFR based on deep understanding in materials science, rather than on the use of mechanistic tools, such as FMEA.
Interfacial Compatibility in Microelectronics provides a clear and methodical resource for graduates and postgraduates alike.
The available books on semiconductor science and technology cannot afford to devote even an entire chapter to photoemissions from optoelectronic materials, although its importance in photoemission spectroscopy is extremely well known. This book deals totally with the photoemission from optoelectronic materials and their nanostructures (ultrathin films, quantum wires, superlattices, etc.).
This comprehensive guide features:Process Analytical Techniques (PAT) used in manufacturing Nanoparticulate Drug Delivery Systems (NPDDS) In-vitro and in-vivo evaluation of NPDDS Applications of novel techniques used in formulation development and characterization, such as microscopic and nonmicroscopic techniques 100 high-quality images
Biological systems have always inspired mankind in the creation of new systems and technologies. In recent years the interfaces between the biological and non-biological worlds appear increasingly blurred due to significant advances both in our understanding of biological phenomena, as well as the development of sophisticated means to manipulate biological systems for varied applications. Biomimetics as a discipline shows how biology and biological processes are manifested in diverse aspects of chemistry, physics and engineering. This book aims to methodically describe artificial and synthetic assemblies mimicking biological and living systems - from drug discovery to microelectronics and computer sciences.
Characterization, modification and understanding of various electrochemical interfaces or electrochemical processes at the nanoscale, has led to a huge increase of the scientific interest in electrochemical mechanisms as well as of application of electrochemical methods in novel technologies. This book presents exciting emerging scientific and technological aspects of the introduction of the nanodimension in electrochemical approaches are presented in 12 chapters/subchapters.
Key new chapters have been included covering eco-toxicity, nanomedicine, informatics, and future threats. New case studies have also been added, including a chapter on the impact of nanosilver on the environment, as well as an assessment of how well lessons have been learned from the past, such as in the case of asbestos. The book also makes a business case for the importance of proactive EHS management - essential reading for existing or prospective producers of nanoscale products.Practical guidance on risk management and mitigation across different legislative frameworks worldwideReviews toxicological studies and industrial initiatives, supported by numerous case studiesIncludes extensive new material on the implications of nanotechnology for medicine, energy and food, as well as assessing future threats.
Part one focuses on the fabrication of nanomaterials for tissue engineering applications and includes chapters on engineering nanoporous biomaterials, layer-by-layer self-assembly techniques for nanostructured devices, and the synthesis of carbon based nanomaterials. Part two goes on to highlight the application of nanomaterials in soft tissue engineering and includes chapters on cardiac, neural, and cartilage tissue engineering. Finally, the use of nanomaterials in hard tissue engineering applications, including bone, dental and craniofacial tissue engineering is discussed in part three.
Nanomaterials in tissue engineering is a standard reference for researchers and tissue engineers with an interest in nanomaterials, laboratories investigating biomaterials, and academics interested in materials science, chemical engineering, biomedical engineering and biological sciences.Explores the fabrication of a variety of nanomaterials and their use across a range of tissue engineering applicationsExamines engineering nanoporous biomaterials, layer-by-layer self-assembly techniques for nanostructured devices, and the synthesis of carbon based nanomaterialsHighlights the application of nanomaterials in soft tissue engineering and includes chapters on cardiac, neural, and cartilage tissue engineering
Dr. Junbai Li is a professor at the National Center for Nanoscience and Technology and the Institute of Chemistry, Chinese Academy of Sciences, China.
General interest was primarily focused on relevant "green chemistry" features related to all types of metathesis reactions (RCM, CM, enyne metathesis, ADMET and ROMP). Diverse opportunities for green and sustainable technologies and industrial procedures based on metahesis have been identified. Largely exemplified was the utility of this broadly applicable strategy in organic synthesis, for accessing natural products and pharmaceuticals, and also its ability to fit in the manufacture of smart and nanostructured materials, self-assemblies with nanoscale morphologies, macromolecular engineering.
This book would be of specific interest for researchers and graduate students in the field of nanoscience, nanotechnology and nanofabrication, material, physical, chemical, electric engineering and biology.
Dr. Weimin Zhou is an associate professor at Shanghai Nanotechnology Promotion Center, China.
The book covers the production process of tuPOY and goes on to conceptual advancement from manipulating the sensing, radiating and processing properties of tuPOY. Theoretical modelling of tuPOY is characterized by steady-state equations exploiting interchanges based on the lattice kinetics, which mathematizes an Interchange Phenomenon in tuPOY. The numerical manifestations calibrate mathematically, tuPOY’s response to any external physical impetus such as charge, heat or energy flow.
The book validates the sensing properties and theoretical model by designing a tuPOY sensor which can be used in a plethora of applications. A novel microstrip antenna is designed by amalgamation of tuPOY, raw silk and polynylon composites to experimentally verify the radiation properties of the new material. The conduction properties are verified by drawing fibres of tuPOY and using them as wires and connectors in electronics. A Power Generating Unit (PGU) is designed with tuPOY as its primary element. This is a first of its kind PGU that scavenges power from thermal energy presenting a new dimension in operational power dynamics.Overall this book should be of interest to a wide range of readers ranging from researchers, scientists, developers, manufacturers, engineers, graduate students and anyone who has satiety to think differently.
The individual volumes in the series are thematic. The goal of each volume is to give the reader, whether at a university or in industry, a comprehensive overview of an area where new insights are emerging that are of interest to a larger scientific audience. Thus each review within the volume critically surveys one aspect of that topic and places it within the context of the volume as a whole. The most significant developments of the last 5 to 10 years should be presented using selected examples to illustrate the principles discussed. A description of the physical basis of the experimental techniques that have been used to provide the primary data may also be appropriate, if it has not been covered in detail elsewhere. The coverage need not be exhaustive in data, but should rather be conceptual, concentrating on the new principles being developed that will allow the reader, who is not a specialist in the area covered, to understand the data presented. Discussion of possible future research directions in the area is welcomed. Review articles for the individual volumes are invited by the volume editors. Readership: research scientists at universities or in industry, graduate students Special offer For all customers who have a standing order to the print version of Structure and Bonding, we offer free access to the electronic volumes of the Series published in the current year via SpringerLink.