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With a selective presentation of topics that makes it accessible for students who have taken introductory university science courses, Understanding Nanomaterials is a training tool for the future workforce in nanotech development. This introductory textbook offers insights into the fundamental principles that govern the fabrication, characterization, and application of nanomaterials. Provides the Background for Fundamental Understanding Assuming only a basic level of competency in physics, chemistry, and biology, the author focuses on the needs of the undergraduate curriculum, discussing important processes such as self-assembly, patterning, and nanolithography. His approach limits mathematical rigor in the presentation of key results and proofs, leaving it to the instructor’s discretion to add more advanced details, or emphasize particular areas of interest. With its combination of discussion-based instruction and explanation of problem-solving skills, this textbook highlights interdisciplinary theory and enabling tools derived from chemistry, biology, physics, medicine, and engineering. It also includes real-world examples related to energy, the environment, and medicine. Author Malkiat S. Johal earned his Ph.D. from the University of Cambridge in England. He later served as a post-doctoral research associate at Los Alamos National Laboratory, New Mexico, where he worked on the nonlinear optical properties of nanoassemblies. Dr. Johal is currently a professor and researcher at Pomona College in Claremont, California. His work focuses on the use of self-assembly and ionic adsorption processes to fabricate nanomaterials for optical and biochemical applications.
Praise for the first edition "clear and informative” ―Chemistry World The authors provide the perfect training tool for the workforce in nanotech development by presenting the fundamental principles that govern the fabrication, characterization, and application of nanomaterials. This edition represents a complete overhaul, giving a much more complete, self-contained introduction. As before, the text avoids excessive mathematical detail and is written in an easy to follow, appealing style suitable for anyone, regardless of background in physics, chemistry, engineering, or biology. The organization has been revised to include fundamental physical chemistry and physics pertaining to relevant electrical, mechanical, and optical material properties. Incorporates new and expanded content on hard materials, semiconductors for nanoelectronics, and nonlinear optical materials. Adds many more worked examples and end-of-chapter problems. Provides more complete coverage of fundamentals including relevant aspects of thermodynamics, kinetics, quantum mechanics, and solid-state physics, and also significantly expands treatment of solid-phase systems. Malkiat S. Johal is a professor of physical chemistry at Pomona College, and earned his doctorate in physical chemistry at the University of Cambridge, UK. Lewis E. Johnson is a research scientist at the University of Washington, where he also earned his doctorate in chemistry and nanotechnology.
An invaluable introduction to nanomaterials and their applications Offering the unique approach of applying traditional physics concepts to explain new phenomena, Introduction to Nanomaterials and Devices provides readers with a solid foundation on the subject of quantum mechanics and introduces the basic concepts of nanomaterials and the devices fabricated from them. Discussion begins with the basis for understanding the basic properties of semiconductors and gradually evolves to cover quantum structures—including single, multiple, and quantum wells—and the properties of nanomaterial systems, such as quantum wires and dots. Written by a renowned specialist in the field, this book features: An introduction to the growth of bulk semiconductors, semiconductor thin films, and semiconductor nanomaterials Information on the application of quantum mechanics to nanomaterial structures and quantum transport Extensive coverage of Maxwell-Boltzmann, Fermi-Dirac, and Bose-Einstein stastistics An in-depth look at optical, electrical, and transport properties Coverage of electronic devices and optoelectronic devices Calculations of the energy levels in periodic potentials, quantum wells, and quantum dots Introduction to Nanomaterials and Devices provides essential groundwork for understanding the behavior and growth of nanomaterials and is a valuable resource for students and practitioners in a field full of possibilities for innovation and invention.
How could nanotechnology not perk the interest of any designer, engineer or architect? Exploring the intriguing new approaches to design that nanotechnologies offer, Nanomaterials, Nanotechnologies and Design is set against the sometimes fantastic sounding potential of this technology. Nanotechnology offers product engineers, designers, architects and consumers a vastly enhanced palette of materials and properties, ranging from the profound to the superficial. It is for engineering and design students and professionals who need to understand enough about the subject to apply it with real meaning to their own work. - World-renowned author team address the hot-topic of nanotechnology - The first book to address and explore the impacts and opportunities of nanotech for mainstream designers, engineers and architects - Full colour production and excellent design: guaranteed to appeal to everyone concerned with good design and the use of new materials
The maturation of nanotechnology has revealed it to be a unique and distinct discipline rather than a specialization within a larger field. Its textbook cannot afford to be a chemistry, physics, or engineering text focused on nano. It must be an integrated, multidisciplinary, and specifically nano textbook. The archetype of the modern nano textbook
This textbook is aimed primarily at the senior undergraduate and first year graduate students from the various engineering and sciences departments including physics, chemistry, materials engineering, chemical engineering, electrical engineering, mechanical engineering, bioengineering, and biology. Researchers in the areas of nanomaterials and nanoscience will also find the book useful for building the background necessary to understand the current literature and as a reference book. The text assumes only a basic level of competency in physics, chemistry and mathematics. Some of the background material and introductory matter are included in the first few chapters and as appendices. Although this material may be familiar to some of the students, it is the author's experience after teaching such a course for many years that this can not be taken for granted and moreover, serves as a ready reference to understand the text.As the area of nanoscience, nanotechnology and nanomaterials is a fast developing one, an approach which equips the students to comprehend the developing field rather than providing a large volume of information is essential. With this in view, while providing a broad perspective, the book emphasizes basics of nanoscience and nanoscale materials and goes into sufficient depth for the reader to be able to handle numerical problems. The treatment is kept at a level which is easily comprehensible to an undergraduate student. Solved examples are provided in each chapter to aid understanding and a set of problems is given at the end of each chapter.
Advancement in the field of nanotechnology has revolutionized the field of medicines and pharmaceuticals in the twentieth century. The proper use of nanomaterials in medical applications requires a proper understanding of these compounds. This correct understanding, beyond the physical and chemical properties, must also have the correct logic of use. In other words, the strategic use of nanomaterials with applicable perspective can also help to advance research, but if we go forward with the current research perspective that leads to the expansion of inapplicable researches, the intrinsic importance of using these nanomaterials is eliminated. This book, considering the importance of nanomaterials and their application in medicine, as well as the significant growth of biomaterials in research fields, introduces the variables law (Rabiee's theory) for the implementation of this research and the establishment of a proper strategy. Considering that the degree of number of biomaterial and host variables follow a variety factors, and by increasing the degree of number of biomaterials and host variables, the degree of total variables also increases and as a result, performance and, consequently, biomaterial behavior in the host environment will have less control and predictive capabilities. For an external substance that is supposed to be in the human body, it must be predictable and controllable, In addition, according to the principle that the host in a fixed person does not have the ability to change, therefore, by using the simpler biomaterials (with less variables), the above goal is more accessible. It should be noted that in addition to observing biocompatibility tests for a biomaterial based on existing protocols and standards, the Applicable Compatibility (AC) parameter is also required in accordance with Rabiee's theory. This book is written in accordance with Rabiee's theory and the contents of this book should be evaluated from this perspective.
An Introduction to Interdisciplinary Toxicology: From Molecules to Man integrates the various aspects of toxicology, from "simple” molecular systems, to complex human communities, with expertise from a spectrum of interacting disciplines. Chapters are written by specialists within a given subject, such as a chemical engineer, nutritional scientist, or a microbiologist, so subjects are clearly explained and discussed within the toxicology context. Many chapters are comparative across species so that students in ecotoxicology learn mammalian toxicology and vice versa. Specific citations, further reading, study questions, and other learning features are also included. The book allows students to concurrently learn concepts in both biomedical and environmental toxicology fields, thus better equipping them for the many career opportunities toxicology provides. This book will also be useful to those wishing to reference how disciplines interact within the broad field of toxicology.
The maturation of nanotechnology has revealed it to be a unique and distinct discipline rather than a specialization within a larger field. Its textbook cannot afford to be a chemistry, physics, or engineering text focused on nano. It must be an integrated, multidisciplinary, and specifically nano textbook. The archetype of the modern nano textbook
As industries strive for greater efficiency and longevity in their metal infrastructure, corrosion remains a persistent and costly adversary. Traditional corrosion inhibitors often fail to provide long-term protection, leading to significant economic losses and environmental harm. Innovations in Nanomaterials-Based Corrosion Inhibitors delves into a thorough exploration of the rapidly evolving field of nanomaterials and their pivotal role in corrosion inhibition. This comprehensive guide offers a transformative solution utilizing the power of nanotechnology to combat corrosion with unparalleled effectiveness. Within the pages of this book lies a wealth of knowledge meticulously curated to address the pressing need for advanced corrosion inhibition strategies. From understanding the fundamental principles of corrosion to exploring the innovative applications of nanomaterials, it equips readers with the tools to revolutionize their approach to metal protection. With a precise analysis of the synthesis, characterization, and practical implementation of diverse nanomaterials, encompassing nanoparticles, nanocomposites, and nanostructured coatings, and a primary focus on safeguarding metal surfaces against corrosion, this book creates the much-needed reference for shaping the future of corrosion inhibitors. Innovations in Nanomaterials-Based Corrosion Inhibitors offers a roadmap to overcoming corrosion challenges and heralding a new era of sustainability and cost-effectiveness. By embracing nanotechnology, industries can enhance the durability of their metal infrastructure while minimizing environmental impact and maximizing economic efficiency.