Nanotechnology is a 'catch-all' description of activities at the level of atoms and molecules that have applications in the real world. A nanometer is a billionth of a meter, about 1/80,000 of the diameter of a human hair, or 10 times the diameter of a hydrogen atom. Nanotechnology is now used in precision engineering, new materials development as well as in electronics; electromechanical systems as well as mainstream biomedical applications in areas such as gene therapy, drug delivery and novel drug discovery techniques. This book present simportant breakthroughs in the field from around the world.
In recent times, polymer nanocomposites have attracted a great deal of scientific interest due to their unique advantages over conventional plastic materials, such as superior strength, modulus, thermal stability, thermal and electrical conductivity, and gas barrier. They are finding real and fast-growing applications in wide-ranging fields such as automotive, aerospace, electronics, packaging, and sports. This book focuses on the development of polymer nanocomposites as an advanced material for textile applications, such as fibers, coatings, and nanofibers. It compiles and details cutting-edge research in the science and nanotechnology of textiles with special reference to polymer nanocomposites in the form of invited chapters from scientists and subject experts from various institutes from all over the world. They include authors who are actively involved in the research and development of polymer nanocomposites with a wide range of functions—including antimicrobial, flame-retardant, gas barrier, shape memory, sensor, and energy-scavenging—as well as medical applications, such as tissue engineering and wound dressings, to create a new range of smart and intelligent textiles. Edited by Mangala Joshi, a prominent nanotechnology researcher at the premier Indian Institute of Technology, Delhi, India, this book will appeal to anyone involved in nanotechnology, nanocomposites, advanced materials, polymers, fibers and textiles, and technical textiles.
Nanotechnology is no longer a merely social talking point and is beginning to affect the lives of everyone. Carbon nanotechnology as a major shaper of new nanotechnologies has evolved into a truly interdisciplinary field, which encompasses chemistry, physics, biology, medicine, materials science and engineering. This is a field in which a huge amount of literature has been generated within recent years, and the number of publications is still increasing every year. Carbon Nanotechnology aims to provide a timely coverage of the recent development in the field with updated reviews and remarks by world-renowned experts. Intended to be an exposition of cutting-edge research and development rather than a kind of conference proceeding, Carbon Nanotechnology will be very useful not only to experienced scientists and engineers, who wish to broaden their knowledge of the wide-ranging nanotechnology and/or to develop practical devices, but also to graduate and senior undergraduate students who look to make their mark in this field of the future.· A comprehensive treatment from materials chemistry and structure-property to practical applications· Offers an in-depth analysis of various carbon nanotechnologies from both fundamental and practical perspectives· An easily accessible assessment of the materials properties and device performances based on all of the major classes of carbon nanomaterials, including: carbon fiber; diamond; C60; and carbon nanotubes· A concise compilation of the practical applications of carbon nanotechnologies from polymer-carbon nanocomposites to sensors, electron emitters, and molecular electronics
The rapid growth of miniaturisation to meet the demand for increasingly smart devices is driving global investment in a wide range of industries such as IT, electronics, energy, biotechnology and materials science. Nanotechnology: Global Strategies, Industry Trends and Applications, written by experts from Asia, Europe and the USA, gives a comprehensive and important global perspective on nanotechnology. The book is divided into 3 parts: National Nanotechnology Initiatives in Asia, Europe and the USAexplores the current status of nanotechnology in China, Korea, Europe and the USA. Investing in Nanotechnology provides practical information about the opportunities and risks involved in nanotechnology and predictions for future growth. Frontiers of Nanotechnology discusses future applications of the technology and the real-world issues surrounding these. Outlining developing trends, emerging opportunities, associated risks and future applications, this book is essential reading for professionals, prospective investors and policy makers who need an accessible introduction to the topic.
The National Nanotechnology Initiative (NNI) is a multiagency, multidisciplinary federal initiative comprising a collection of research programs and other activities funded by the participating agencies and linked by the vision of "a future in which the ability to understand and control matter at the nanoscale leads to a revolution in technology and industry that benefits society." As first stated in the 2004 NNI strategic plan, the participating agencies intend to make progress in realizing that vision by working toward four goals. Planning, coordination, and management of the NNI are carried out by the interagency Nanoscale Science, Engineering, and Technology (NSET) Subcommittee of the National Science and Technology Council (NSTC) Committee on Technology (CoT) with support from the National Nanotechnology Coordination Office (NNCO). Triennial Review of the National Nanotechnology Initiative is the latest National Research Council review of the NNI, an assessment called for by the 21st Century Nanotechnology Research and Development Act of 2003. The overall objective of the review is to make recommendations to the NSET Subcommittee and the NNCO that will improve the NNI's value for basic and applied research and for development of applications in nanotechnology that will provide economic, societal, and national security benefits to the United States. In its assessment, the committee found it important to understand in some detail-and to describe in its report-the NNI's structure and organization; how the NNI fits within the larger federal research enterprise, as well as how it can and should be organized for management purposes; and the initiative's various stakeholders and their roles with respect to research. Because technology transfer, one of the four NNI goals, is dependent on management and coordination, the committee chose to address the topic of technology transfer last, following its discussion of definitions of success and metrics for assessing progress toward achieving the four goals and management and coordination. Addressing its tasks in this order would, the committee hoped, better reflect the logic of its approach to review of the NNI. Triennial Review of the National Nanotechnology Initiative also provides concluding remarks in the last chapter.
As long as humans have existed on the planet, they have looked at the world around them and wondered about much of what they saw. This book covers 21 different phenomena that have been observed in nature and puzzled about for decades.Only recently, with the development of the microscopes and other tools that allow us to study, evaluate, and test these observed phenomena at the molecular and atomic scale, have researchers been able to understand the science behind these observations. From the strength of a marine sponge found at the depths of the oceans, to the insect-hydroplaning surface of the edge of a plant, to the intricacies of the eyes of a moth, nanotechnology has allowed science to define and understand these amazing capabilities. In many cases, this new understanding has been applied to products and applications that benefit humans and the environment. For each of the five ecosystems— the ocean, insects, flora, fauna, and humans—the observations, study and understanding, and applications will be covered. The relationship between the more easily observed macro level and understanding what is found at the nanoscale will also be discussed.
Focusing on the cutting-edge technologies available in the field of photovoltaics, Solar Cell Nanotechnology explores the latest research and development activities related to organic, inorganic, and hybrid materials being used in solar cell manufacturing. Several chapters are dedicated to explaining the fundamentals of photovoltaics and nanomaterials utilized in the manufacturing of solar cells. Other essential subjects, such as microcontact printing, plasmonic light trapping, outdoor and indoor efficiency, luminescent solar concentrators, and photon management in photovoltaics, are comprehensively reviewed. Written for a broad audience, this is an essential book for engineers, nanotechnologists, and materials scientists.
The nanotech revolution waits for no man, woman...or child. To revitalize science, technology, engineering, and mathematics (STEM) performance, the U.S. educational system requires a practical strategy to better educate students about nanoscale science and engineering research. This is particularly important in grades K–12, the effective gestation point for future ideas and information. 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.
"We need to seamlessly integrate IPR in the standard graduate/post graduate courses in science, technology, commerce, creative arts, etc., without over burdening the students with law" —Dr Prabuddha Ganguli, CEO, VISION-IPR Nanotechnology Intellectual Property Rights: Research, Design, and Commercialization offers an overview of the dynamics of development and commercialization in nanotech, where strategic integration of IP, R&D, and commercialization has become imperative. It demystifies issues of intellectual property rights (IPR) associated with research, design, technology transfer, and commercialization of innovations in technology-led areas such as nanotech. Gives all stakeholders vital information to instill confidence by helping them better understand their individual roles in the IPR process Designed for a diverse readership that may not have background knowledge of the legal nuances of IPR, this book clearly articulates techno-legal aspects of nano-related innovations to aid their effective integration into businesses. This resource stands apart by using numerous case studies and pictorial illustrations, addressing aspects ranging from ideation to commercialization of IP-enabled nanotechnology. It illustrates the evolving patent landscape in nanotechnology, explores the international patent classification system, and details patenting procedures in a range of jurisdictions, including search for nanotechnology prior art and creation of search strategies. The authors discuss patent-led nanotechnology businesses, presenting a wide range of case studies that address construction of valuable patent portfolios, growth of start-ups, and consolidation of IP-led nanobusinesses through mergers, acquisitions, joint ventures, strategic investments, etc. They also cover patent litigations in nanotechnologies and the significance of strategically crafting agreements related to IP transactions. In addition, they address compliance with contractual obligations, the importance of well-drafted patent specifications, and sensitive aspects of conducting techno-legal due diligence prior to the development and marketing of products. Also covered are vulnerabilities in challenging/defending the validity of patents and negotiating settlements. Integrating use of the IPRinternalise® model for capacity building in human and infrastructural resources, the authors assess the future of IP landscaping in nanotechnology. Here, they focus on patentability, public perception of risks to health and ecosystems, institutionalized management of intellectual property rights, and the steps that will be necessary to meet these and other such challenges on the way to realizing profits in nanotech.