ORGANIC NANOCHEMISTRY How-to guide for entry-level practitioners to quickly learn the cutting-edge research concepts and methodologies of modern organic nanochemistry Organic Nanochemistry describes the fundamentals of organic nanochemistry research, encompassing modern synthetic reactions, supramolecular strategies, nanostructure and property characterization techniques, and state-of-the-art data analysis and processing methods, along with synthetic chemistry as applied to organic nanomaterials and molecular devices. Accompanying each of these principles are case studies (from basic design to detailed experimental implementation) to help the reader fully comprehend the concepts and methods involved. Various theories suitable for nanoscale simulations, including quantum mechanics, semi-empirical quantum mechanics, and molecular dynamics theories, are discussed at an introductory level. Computational examples are provided, allowing interested readers to grasp essential modelling techniques for better understanding of organic nanochemistry. The content is paired with online supplementary material that includes instructional materials and guides to using common scientific software for computational modelling and simulations. Written by a highly qualified professor, Organic Nanochemistry includes discussion on: Key concepts and theories of organic chemistry, which are essential to understand the fundamental properties of organic molecular and supramolecular systems Useful synthetic methodologies for the synthesis and functionalization of organic nanomaterials, and the chemistry and application of exotic carbon nanomaterials Supramolecular aspects in organic nanochemistry, especially the well-developed disciplines of host-guest chemistry and organic self-assembly chemistry Construction and testing of molecular devices and molecular machines and state-of-the-art computational modelling methods for properties of nanoscale organic systems Guiding the reader on a journey from familiar chemical concepts and principles to cutting-edge research of nano-science and technology, Organic Nanochemistry serves as an excellent textbook learning resource for advanced and graduate students, as well as a self-study guide or how-to reference for practicing chemists.

Organic chemistry is the chemistry of compounds of carbon. The ability of carbon to link together to form long chain molecules and ring compounds as well as bonding with many other elements has led to a vast array of organic compounds. These compounds are central to life, forming the basis for organic molecules such as nucleic acids, proteins, carbohydrates, and lipids. In this Very Short Introduction Graham Patrick covers the whole range of organic compounds and their roles. Beginning with the structures and properties of the basic groups of organic compounds, he goes on to consider organic compounds in the areas of pharmaceuticals, polymers, food and drink, petrochemicals, and nanotechnology. He looks at how new materials, in particular the single layer form of carbon called graphene, are opening up exciting new possibilities for applications, and discusses the particular challenges of working with carbon compounds, many of which are colourless. Patrick also discusses techniques used in the field. ABOUT THE SERIES: The Very Short Introductions series from Oxford University Press contains hundreds of titles in almost every subject area. These pocket-sized books are the perfect way to get ahead in a new subject quickly. Our expert authors combine facts, analysis, perspective, new ideas, and enthusiasm to make interesting and challenging topics highly readable.

The second edition of Nanochemistry covers the main studies of nanoparticle production, reactions, and compounds, and reviews the work of leading scientists from around the world. This book is the first monograph on nanochemistry, giving perspectives on the present status and future possibilities in this rapidly advancing discipline. It provides the solid fundamentals and theory of nanoscience, and progress through topics including synthesis and stabilization of nanoparticles, cryochemistry of metal atoms and nanoparticles, chemical nanoreactors, and more. Nanoparticles are capable of transformations that have already led to revolutionary applications, including reagents for self-cleaning glass surfaces and fabrics, different antiseptic coverings, sensors for monitoring the environment and catalysts mitigating pollution. Leads the reader through the theory, research and key applications of nanochemistry, providing a thorough reference for researchers 40% more content than the first edition and an expanded author team Reviews new advances in the field, including organic nanoparticles and key methods for making nanoparticles (e.g. solvated metal atom dispersion and self-assembly techniques)

Nanochemistry: Chemistry of Nanoparticle Formation and Interactions provides an overview of the chemistry aspects of nanoparticle science, including nanoparticle synthesis, chemical properties, stability, applications and self-assembly behavior. The critical concepts discussed in this book represent the necessary toolbox for enabling the rational design of nanoparticle-based materials for target applications. After an introduction to standard analytical techniques used for nanoparticle characterization, four separate chapters cover inorganic, organic, polymer nanoparticles, and carbon nanostructures to highlight the synthetic protocols, structural intricacies, and chemical properties specific to each of these material classes. Finally, physicochemical phenomena governing self-assembly behavior of nanoparticles are also discussed in detail separately. This book is intended for senior undergraduate, graduate and postgraduate students and research scientists in nanoscience and nanotechnology, material science, chemistry, physics, biomedical sciences and relevant engineering fields that want to develop a deeper understanding of the governing chemical principles on the nanoscale. - Provides an up-to-date text reflecting the latest changes in the field, acting as a fully restructured successor text to Nanochemistry, 2nd Edition (Elsevier, 2013) by Klabunde and Sergeev - Leads the reader through the fundamental concepts and illustrative examples of inorganic, organic, and polymer nanoparticle formation, discussing, in detail, the aspects of synthetic geometry control, surface chemistry, and nanoparticle stability - Provides in-depth coverage of nanoparticle self-assembly behavior, including the self-assembly driving forces and approaches to control this process through nanoparticle design and environmental cues

International interest in nanoscience research has flourished in recent years, as it becomes an integral part in the development of future technologies. The diverse, interdisciplinary nature of nanoscience means effective communication between disciplines is pivotal in the successful utilization of the science. Nanochemistry: A Chemical Approach to Nanomaterials is the first textbook for teaching nanochemistry and adopts an interdisciplinary and comprehensive approach to the subject. It presents a basic chemical strategy for making nanomaterials and describes some of the principles of materials self-assembly over 'all' scales. It demonstrates how nanometre and micrometre scale building blocks (with a wide range of shapes, compositions and surface functionalities) can be coerced through chemistry to organize spontaneously into unprecedented structures, which can serve as tailored functional materials. Suggestions of new ways to tackle research problems and speculations on how to think about assembling the future of nanotechnology are given. Primarily designed for teaching, this book will appeal to graduate and advanced undergraduate students. It is well illustrated with graphical representations of the structure and form of nanomaterials and contains problem sets as well as other pedagogical features such as further reading, case studies and a comprehensive bibliography.

New Frontiers in Nanochemistry: Concepts, Theories, and Trends, Volume 1: Structural Nanochemistry is the first volume of the new three-volume set that explains and explores the important concepts from various areas within the nanosciences. This first volume focuses on structural nanochemistry and encompasses the general fundamental aspects of nanochemistry while simultaneously incorporating crucial material from other fields, in particular mathematic and natural sciences, with specific attention to multidisciplinary chemistry. Under the broad expertise of the editor, the volume contains 50 concise yet comprehensive entries from world-renowned scholars, alphabetically organizing a multitude of essential basic and advanced concepts, ranging from algebraic chemistry to new energy technology, from the bondonic theory of chemistry to spintronics, and from fractal dimension and kinetics to quantum dots and tight binding—and much more. The entries contain definitions, short characterizations, uses and usefulness, limitations, references, and more.

Analytical Nanochemistry provides readers with a comprehensive review of the application of nanomaterial in analytical chemistry. It explains the fundamental concepts involved in utilizing nanomaterials including their classification, synthesis, functionalization, characterization methods, separation, and isolation techniques, as well as toxicity. It also covers fundamental information on different aspects of analytical procedures and method development. Furthermore, it emphasizes micro- and nano-enabled analytical devices and instruments as well as nanotools for nanoanalysis. The book opens with a section on fundamentals (Section 1), then continues with a section on the role of nanomaterials in analytical procedures (Section 2), including sample preparation, separation, and detection. The third section (Section 3) includes chapters on micro- and nano-enabled devices, as most miniaturized microsystems include nanofeatures. The book concludes with a fourth section (Section 4) on future perspectives, covering nanoanalysis, bioanalysis, toxic risks, and limitations of both technology and commercialization. This book serves as a valuable resource for students, instructors, and researchers in analytical chemistry, nanomaterials, and nanotechnology investigating the use of nanotechnology in their analytical procedures. - Covers the synthesis methods, functionalization process, and characterization methods of nanomaterials - Uses numerous visual elements to illustrate key points, including flowcharts, process diagrams, photographs, and visual schemes - Presents fundamental concepts and updated hot topics such as miniaturization in analytical chemistry, nanotools for nano-analysis, micro total analysis systems, and lab-on-a-chip