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Thorough and up-to-date, this book presents recent developments in this exciting research field. To begin with, the text covers the fabrication of chiral nanomaterials via various synthesis methods, including electron beam lithography, ion beam etching, chemical synthesis and biological DNA directed assembly. This is followed by the relevant theory and reaction mechanisms, with a discussion of the characterization of chiral nanomaterials according to the optical properties of metal nanoparticles, semiconductor nanocrystals, and nanoclusters. The whole is rounded off by a summary of applications in the field of catalysis, sensors, and biomedicine. With its comprehensive yet concise coverage of the whole spectrum of research, this is invaluable reading for senior researchers and entrants to the field of nanoscience and materials science.
Thorough and up-to-date, this book presents recent developments in this exciting research field. To begin with, the text covers the fabrication of chiral nanomaterials via various synthesis methods, including electron beam lithography, ion beam etching, chemical synthesis and biological DNA directed assembly. This is followed by the relevant theory and reaction mechanisms, with a discussion of the characterization of chiral nanomaterials according to the optical properties of metal nanoparticles, semiconductor nanocrystals, and nanoclusters. The whole is rounded off by a summary of applications in the field of catalysis, sensors, and biomedicine. With its comprehensive yet concise coverage of the whole spectrum of research, this is invaluable reading for senior researchers and entrants to the field of nanoscience and materials science.
A comprehensive overview exploring the biological applications of chiral nanomaterials Chirality has been the centerpiece of many multidisciplinary fields within the broader umbrella of the sciences. Recent advancements in nanoscience have spurred a growing interest in the dynamic field of chiral nanomaterials. In particular, the recent breakthroughs in chiral nanocrystals have presented an intriguing avenue whose potential application may address some key issues at the heart of nanosciences. While little attention has been focused on the biological implications of such advances, this arena is attracting theoretical and applicative interests. Seeking to provide a thorough introduction to the field as well as fill this gap in scholarship, Chiral Nanoprobes for Biological Applications first provides a comprehensive review of the state-of-the-art development of strong chiroptical nanomaterials, describing how a synthesis and self-assembly approach can enable one to design and create a number of functional chiral nanomaterials. From there, the authors discuss the biological applications of chiral nanomaterials, such as extracellular bioanalysis, intracellular bioanalysis, and chiral recognition, as well as photothermal and photodynamics therapy. In doing so, the book seeks emphasize the potential in multidisciplinary approaches to this up-and-coming field. Chiral Nanoprobes for Biological Applications readers will also find: A particular emphasis on milestones achieved for key chiral nanoprobes research from the last five years A discussion of future research directions A helpful guide for new researchers and established professionals alike Chiral Nanoprobes for Biological Applications is a useful reference for materials scientists, biochemists, protein chemists, stereo chemists, polymer chemists, and physical chemists. It is also a useful tool for libraries.
The only standard reference in this exciting new field combines the physical, chemical and material science perspectives in a synergic way. This monograph traces the development of the preparative methods employed to create nanostructures, in addition to the experimental techniques used to characterize them, as well as some of the surprising physical effects. The chapters cover every category of material, from organic to coordination compounds, metals and composites, in zero, one, two and three dimensions. The book also reviews structural, chemical, optical, and other physical properties, finishing with a look at the future for chiral nanosystems.
A comprehensive overview exploring the biological applications of chiral nanomaterials Chirality has been the centerpiece of many multidisciplinary fields within the broader umbrella of the sciences. Recent advancements in nanoscience have spurred a growing interest in the dynamic field of chiral nanomaterials. In particular, the recent breakthroughs in chiral nanocrystals have presented an intriguing avenue whose potential application may address some key issues at the heart of nanosciences. While little attention has been focused on the biological implications of such advances, this arena is attracting theoretical and applicative interests. Seeking to provide a thorough introduction to the field as well as fill this gap in scholarship, Chiral Nanoprobes for Biological Applications first provides a comprehensive review of the state-of-the-art development of strong chiroptical nanomaterials, describing how a synthesis and self-assembly approach can enable one to design and create a number of functional chiral nanomaterials. From there, the authors discuss the biological applications of chiral nanomaterials, such as extracellular bioanalysis, intracellular bioanalysis, and chiral recognition, as well as photothermal and photodynamics therapy. In doing so, the book seeks emphasize the potential in multidisciplinary approaches to this up-and-coming field. Chiral Nanoprobes for Biological Applications readers will also find: A particular emphasis on milestones achieved for key chiral nanoprobes research from the last five years A discussion of future research directions A helpful guide for new researchers and established professionals alike Chiral Nanoprobes for Biological Applications is a useful reference for materials scientists, biochemists, protein chemists, stereo chemists, polymer chemists, and physical chemists. It is also a useful tool for libraries.
Discover a new generation of organic nanomaterials and their applications Recent developments in nanoscience and nanotechnology have given rise to a new generation of functional organic nanomaterials with controlled morphology and well-defined properties, which enable a broad range of useful applications. This book explores some of the most important of these organic nanomaterials, describing how they are synthesized and characterized. Moreover, the book explains how researchers have incorporated organic nanomaterials into devices for real-world applications. Featuring contributions from an international team of leading nanoscientists, Organic Nanomaterials is divided into five parts: Part One introduces the fundamentals of nanomaterials and self-assembled nanostructures Part Two examines carbon nanostructures—from fullerenes to carbon nanotubes to graphene—reporting on properties, theoretical studies, and applications Part Three investigates key aspects of some inorganic materials, self-assembled monolayers, organic field effect transistors, and molecular self-assembly at solid surfaces Part Four explores topics that involve both biological aspects and nanomaterials such as biofunctionalized surfaces Part Five offers detailed examples of how organic nanomaterials enhance sensors and molecular photovoltaics Most of the chapters end with a summary highlighting the key points. References at the end of each chapter guide readers to the growing body of original research reports and reviews in the field. Reflecting the interdisciplinary nature of organic nanomaterials, this book is recommended for researchers in chemistry, physics, materials science, polymer science, and chemical and materials engineering. All readers will learn the principles of synthesizing and characterizing new organic nanomaterials in order to support a broad range of exciting new applications.
Discover a new generation of organic nanomaterials and their applications Recent developments in nanoscience and nanotechnology have given rise to a new generation of functional organic nanomaterials with controlled morphology and well-defined properties, which enable a broad range of useful applications. This book explores some of the most important of these organic nanomaterials, describing how they are synthesized and characterized. Moreover, the book explains how researchers have incorporated organic nanomaterials into devices for real-world applications. Featuring contributions from an international team of leading nanoscientists, Organic Nanomaterials is divided into five parts: Part One introduces the fundamentals of nanomaterials and self-assembled nanostructures Part Two examines carbon nanostructures from fullerenes to carbon nanotubes to graphene reporting on properties, theoretical studies, and applications Part Three investigates key aspects of some inorganic materials, self-assembled monolayers, organic field effect transistors, and molecular self-assembly at solid surfaces Part Four explores topics that involve both biological aspects and nanomaterials such as biofunctionalized surfaces Part Five offers detailed examples of how organic nanomaterials enhance sensors and molecular photovoltaics Most of the chapters end with a summary highlighting the key points. References at the end of each chapter guide readers to the growing body of original research reports and reviews in the field. Reflecting the interdisciplinary nature of organic nanomaterials, this book is recommended for researchers in chemistry, physics, materials science, polymer science, and chemical and materials engineering. All readers will learn the principles of synthesizing and characterizing new organic nanomaterials in order to support a broad range of exciting new applications.
The field of nanoscience continues to grow at an impressive rate, with over 10,000 new articles a year contributing to more than half a million citations. Such a vast landscape of material requires careful examination to uncover the most important discoveries. Nanoscience, edited by Professor Paul O’Brien (University of Manchester) and Dr John Thomas (Bangor University), presents a critical and comprehensive assessment of the last twelve months of research and discussion. With contributions from around the globe, this series ensures readers will be well-versed in the latest research and methodologies. Chapters cover a range of topics, including ‘Mesocrystals’, ‘Quantum dot synthesis’, ‘Nano and energy storage’ and ‘Beyond graphene’. Anyone practicing in a nano-allied field, or wishing to enter the nano-world, will benefit from the publication of this comprehensive resource annually.
In this book anisotropic one-dimensional and two-dimensional nanoscale building blocks and their assembly into fascinating and qualitatively new functional structures embracing both hard and soft components are explained. Contributions from leading experts regarding important aspects like synthesis, assembly, properties and applications of the above materials are compiled into a reference book. The anisotropy, i.e. the direction-dependent physical properties, of materials is fascinating and elegant and has sparked the quest for anisotropic materials with useful properties. With such a curiosity, material scientists have ventured into the realm of nanometer length scale and have explored the anisotropic nanoscale building blocks such as metallic and nonmetallic particles as well as organic molecular aggregates. It turns out that the anisotropic nanoscale building blocks, in addition to direction-dependent properties, exhibit dimension and morphology dependence of physical properties. Moreover, ordered arrays of anisotropic nanoscale building blocks furnish novel properties into the resulting system which would be entirely different from the properties of individual ones. Undoubtedly, these promising properties have qualified them as enabling building blocks of 21st century materials science, nanoscience and nanotechnology. Readers will find this book professionally valuable and intellectually stimulating in the rapidly emerging area of anisotropic nanomaterials. Quan Li, Ph.D., is Director of the Organic Synthesis and Advanced Materials Laboratory at the Liquid Crystal Institute of Kent State University, where he is also Adjunct Professor in the Chemical Physics Interdisciplinary Program. He has directed research projects funded by US Air Force Research Laboratory (AFRL), US Air Force Office of Scientific Research (AFSOR), US Army Research Office (ARO), US Department of Defense Multidisciplinary University Research Initiative (DoD MURI), US National Science Foundation (NSF), US Department of Energy (DOE), US National Aeronautics and Space Administration (NASA), Ohio Third Frontier, and Samsung Electronics, among others.