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Carbon atoms have the amazing ability to bond in remarkable different manners that can assume distinct astonishing dimensional arrangements from which absolutely diverse and interesting nanostructured carbon materials are obtained. This book aims to cover the most recent advances in (i) Graphene and derivatives, including graphene-based magnetic composites, membranes, wafer devices, and nanofibers for several applications, as well as some particular properties, such as light emission from graphene; (ii) Carbon nanotubes heaters and fibers for reinforcement of cement and diamond-based thin films; and (iii) Nanofluids consisting of both graphene and carbon nanotubes, apart from reporting some important case studies dealing with carbon nanostructures and their use in sensors, coatings, or electromagnetic wave absorbers.
Topological Modelling of Nanostructures and Extended Systems completes and expands upon the previously published title within this series: The Mathematics and Topology of Fullerenes (Vol. 4, 2011) by gathering the latest research and advances in materials science at nanoscale. It introduces a new speculative area and novel concepts like topochemical reactions and colored reactive topological indices and provides a better understanding of the physical-chemical behaviors of extended systems. Moreover, a charming new family of space-filling fullerenic crystals is here analyzed for the first time. Particular attention is given to the fundamental influences exercised by long-range connectivity topological mechanisms on the chemical and physical properties of carbon nanostructures. Systems consisting in graphenic layers with structural and topological defects are investigated in their electronic and magnetic behaviors also in presence of metallic particles. More specifically, the book focuses on: - Electronic Properties of low dimensional nanostructures including negatively-curved carbon surfaces; Pariser-Parr-Pople model hamiltonian approach to graphene studies; - Topochemistry and Toporeactcivity of extended sp2-nanocarbons: PAH, fullerenes, nanoribbons, Moebius-like nanoribbons, nanotubes and grapheme; - Novel class of crystal networks arising from spanning fullerenes; - Nanostructures and eigenvectors of matrices and an extended treatise of topological invariants; - Enumeration hetero-fullerenes by Polya theory. Topological Modelling of Nanostructures and Extended Systems represents a valuable resource to advances graduates and researchers working in mathematics, chemistry, physics and material science.
This book highlights all newly reported carbon nanostructures including graphene and its derivatives, carbon nanotubes, metal organic frameworks, fullerenes, nanorods, nanospheres, nano onions, porous nanoparticles, nanohorns, nanofibers and nanoribbons, nanodiamonds, graphitic carbon nitrides, carbon aerogels and hydrogels, graphdiyne and graphenylene. It presents the historical development of carbon nanostructures technologies, different types and classifications, and different fabrication and functionalization techniques, including outer/inner surface functionalization and covalent and noncovalent functionalization. This Handbook discusses the unique properties of functionalized carbon nanostructures that can be obtained by modifying their structures, composition, and surface. It gives the reader an in-depth look at the current achievements of research and practice while pointing you ahead to new possibilities in functionalizing and using carbon nanomaterials. Finally, it covers the various applications of functionalized carbon nanostructures including adsorbents, additives, active materials in energy accumulating systems (batteries, hydrogen storage systems, and supercapacitors), filtering media, catalysts or supports for catalysts, sensors or substrates for sensors, additives for polymers, ceramic composites, metal and carbon alloys, glasses, digital textiles, and composite materials.
Graphene is the strongest material ever studied and can be an efficient substitute for silicon. This six-volume handbook focuses on fabrication methods, nanostructure and atomic arrangement, electrical and optical properties, mechanical and chemical properties, size-dependent properties, and applications and industrialization. There is no other major reference work of this scope on the topic of graphene, which is one of the most researched materials of the twenty-first century. The set includes contributions from top researchers in the field and a foreword written by two Nobel laureates in physics. Volumes in the set: K20503 Graphene Science Handbook: Mechanical and Chemical Properties (ISBN: 9781466591233) K20505 Graphene Science Handbook: Fabrication Methods (ISBN: 9781466591271) K20507 Graphene Science Handbook: Electrical and Optical Properties (ISBN: 9781466591318) K20508 Graphene Science Handbook: Applications and Industrialization (ISBN: 9781466591332) K20509 Graphene Science Handbook: Size-Dependent Properties (ISBN: 9781466591356) K20510 Graphene Science Handbook: Nanostructure and Atomic Arrangement (ISBN: 9781466591370)
Discover the Unique Electron Transport Properties of GrapheneThe Graphene Science Handbook is a six-volume set that describes graphene's special structural, electrical, and chemical properties. The book considers how these properties can be used in different applications (including the development of batteries, fuel cells, photovoltaic cells, and s
Defects in Advanced Electronic Materials and Novel Low Dimensional Structures provides a comprehensive review on the recent progress in solving defect issues and deliberate defect engineering in novel material systems. It begins with an overview of point defects in ZnO and group-III nitrides, including irradiation-induced defects, and then look at defects in one and two-dimensional materials, including carbon nanotubes and graphene. Next, it examines the ways that defects can expand the potential applications of semiconductors, such as energy upconversion and quantum processing. The book concludes with a look at the latest advances in theory. While defect physics is extensively reviewed for conventional bulk semiconductors, the same is far from being true for novel material systems, such as low-dimensional 1D and 0D nanostructures and 2D monolayers. This book fills that necessary gap. - Presents an in-depth overview of both conventional bulk semiconductors and low-dimensional, novel material systems, such as 1D structures and 2D monolayers - Addresses a range of defects in a variety of systems, providing a comparative approach - Includes sections on advances in theory that provide insights on where this body of research might lead
This book gives a detailed and up-to-date overview of the linearized augmented cylindrical wave (LACW) technique for nanotubes and nanowires. The author presents the mathematical foundations together with numerous applications. Method for calculating the electronic structure of point impurities, which is based on a combination of the LACW and Green’s functions techniques, is presented. The book clearly demonstrates how the relativistic effects can be incorporated into LACW approach and how the spin-orbit coupling effects change the tubules band structure. Extensive illustrations of application to the inorganic nanotubes and nanowires make the book essential reading in this field above all.
This book describes carbon nanothreads with complete and comprehensive knowledge covering theories, numerical methods, and properties comparisons with other carbon-based nanomaterials. For one thing, the main theoretical aspects in this book include: First-Principle Calculation, Density Functional Theory, Classical Molecular Dynamics Simulation, Non-equilibrium Molecular Dynamics Simulation, and Coarse Grained Simulation. For another thing, the main research contents include: Fundamental Mechanical Properties; Fracture Characteristics; Electronic and Magnetic Properties; Thermal Properties; Reinforcement in Polymer Composites; and other promising applications in engineering. The target of this book is to provide to many researchers the available theoretical and numerical methods, and useful computational results of carbon nanothreads for reference. This book can be used as a comprehensive source for scientists, academics, researchers, and engineers in various areas of engineering, physical sciences, and computational modeling. In order to achieve this target, the book introduces the microstructure information of carbon nanothreads and the modeling details at full length. The tunable mechanisms of physical properties of carbon nanothreads are discussed in detail, which enable integration of these nanoscale components into high-order structures for “bottom-up design” purpose. The revealed reinforced mechanisms of carbon nanothreads in polymer composites can provide theoretical guidance for engineering design of advanced polymer composites.
Carbon nanotubes (CNTs), discovered in 1991, have been a subject of intensive research for a wide range of applications. These one-dimensional (1D) graphene sheets rolled into a tubular form have been the target of many researchers around the world. This book concentrates on the semiconductor physics of carbon nanotubes, it brings unique insight into the phenomena encountered in the electronic structure when operating with carbon nanotubes. This book also presents to reader useful information on the fabrication and applications of these outstanding materials. The main objective of this book is to give in-depth understanding of the physics and electronic structure of carbon nanotubes. Readers of this book should have a strong background on physical electronics and semiconductor device physics. This book first discusses fabrication techniques followed by an analysis on the physical properties of carbon nanotubes, including density of states and electronic structures. Ultimately, the book pursues a significant amount of work in the industry applications of carbon nanotubes.
Applications of Multifunctional Nanomaterials showcases the major applications of highly correlated nanosystems that highlight the multifunctionality of nanomaterials. This includes applications of nanomaterials in spintronics, information storage, magnetic data storage and memory device applications, energy harvesting applications using nanomultiferroics with piezoelectric polymers, nonlinear optical limiting applications using graphene or ferrite nanoparticles, soft tissues applications, EMI shielding applications and even applications in sunscreen lotions, cosmetics and food packaging will be discussed. In addition, nanoparticle incorporation in animal nutrition intended for increased productivity is an innovative and groundbreaking theme of the book. Finally, functionalized magnetic nanoparticles for drug delivery, magnetic hyperthermia, sutures, cancer therapy, dentistry and other biomedical and bio-engineering applications using nanoparticles are discussed in detail. - Explains the major design and fabrication techniques and processes for a range of multifunctional nanomaterials and nanotechnologies - Demonstrates how ferromagnetics, multiferroics and carbon nanomaterials are designed for electronic and optical applications - Assesses the major challenges of using multifunctional nanomaterials on a mass scale