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​This book presents an analysis of the techniques used for the synthesis of innovative functional carbon nanostructures. The chapters describe the research and development of various layered carbon nanostructures. Emphasis is given to the impact of defects on carbon nanostructures. The application of carbon nanostructured materials in biomedical field and energy storage is described.
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.
Defects in Two-Dimensional Materials addresses the fundamental physics and chemistry of defects in 2D materials and their effects on physical, electrical and optical properties. The book explores 2D materials such as graphene, hexagonal boron nitride (h-BN) and transition metal dichalcogenides (TMD). This knowledge will enable scientists and engineers to tune 2D materials properties to meet specific application requirements. The book reviews the techniques to characterize 2D material defects and compares the defects present in the various 2D materials (e.g. graphene, h-BN, TMDs, phosphorene, silicene, etc.). As two-dimensional materials research and development is a fast-growing field that could lead to many industrial applications, the primary objective of this book is to review, discuss and present opportunities in controlling defects in these materials to improve device performance in general or use the defects in a controlled way for novel applications. Presents the theory, physics and chemistry of 2D materials Catalogues defects of 2D materials and their impacts on materials properties and performance Reviews methods to characterize, control and engineer defects in 2D materials
This book presents a widespread description of the synthesis and characterization of biomass-based carbon nanostructures. It also covers the vital applications of these materials in supercapacitors and for next-generation energy storage devices. It describes the common design procedures, advantages and disadvantages of biomass-based carbon nanostructures and offers novel visions into the forthcoming directions. In addition, this book will provide new updates about the effect of doping and structural twist on the electrochemical performance of electrode materials derived from biomass sources. The book will be useful for beginners, researchers, and professionals working in the area of carbon nanomaterials and their applications in energy storage devices.
Bio-derived Carbon Nanostructures: Fundamentals, Synthesis and Applications explores the entire journey, from selecting the right source materials to crafting them into precisely engineered carbon nanostructures with a purpose.Opening with an exploration of raw materials and their structural intricacies, offering readers a profound insight into the transformation of bio-based resources into highly functional carbon nanostructures. These remarkable materials find applications that span energy, environmental solutions, catalysis, and innovative additives. Unveiling the latest technological advancements, this book delves into the exciting realm of emerging applications and the challenges of scaling up these technologies for widespread use. These novel materials originate from nature, promising a sustainable future.Ideal for students, researchers and those in industry focusing on materials science and biomass utilization, and chemical engineers, this book is the key to unlocking the potential of novel carbon-based nanomaterials for a sustainable tomorrow. - Presents the art of crafting bio-derived carbon nanostructures, their applications, and scale up issues - Unveils the secrets behind various fabrication techniques and provides background for manufacturing. - Embarks on a journey through the fundamentals of process-property relationships and cutting-edge characterization methods - Explores and compares diverse preparation and characterization techniques, unveiling their remarkable outcomes
Beginning with an introduction to carbon-based nanomaterials, their electronic properties, and general concepts in quantum transport, this detailed primer describes the most effective theoretical and computational methods and tools for simulating the electronic structure and transport properties of graphene-based systems. Transport concepts are clearly presented through simple models, enabling comparison with analytical treatments, and multiscale quantum transport methodologies are introduced and developed in a straightforward way, demonstrating a range of methods for tackling the modelling of defects and impurities in more complex graphene-based materials. The authors also discuss the practical applications of this revolutionary nanomaterial, contemporary challenges in theory and simulation, and long-term perspectives. Containing numerous problems for solution, real-life examples of current research, and accompanied online by further exercises, solutions and computational codes, this is the perfect introductory resource for graduate students and researchers in nanoscience and nanotechnology, condensed matter physics, materials science and nanoelectronics.
Third-generation solar cells (SCs) are built on inorganic nanoparticles, hybrids, or semiconducting organic macromolecules. This book focuses on dye-sensitized solar cells, polymer/organic solar cells, copper/zinc/tin sulfide thin film cells, quantum dot solar cells and perovskite-based solar cells. Specific topics covered include device architecture, interface engineering, characterization, and fabrication techniques such as spin coating, blade coating, slot-die coating, dip coating, meniscus coating, spray coating, ink-jet printing, screen printing and electro deposition. Keywords: Fullerene-Containing Polymers, Light-Sensitive Dye, Organic Solar Cells, Perovskite Film, Quantum Dots, Thin Film Solar Cells.
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
Uncertainty Quantification of Stochastic Defects in Materials investigates the uncertainty quantification methods for stochastic defects in material microstructures. It provides effective supplementary approaches for conventional experimental observation with the consideration of stochastic factors and uncertainty propagation. Pursuing a comprehensive numerical analytical system, this book establishes a fundamental framework for this topic, while emphasizing the importance of stochastic and uncertainty quantification analysis and the significant influence of microstructure defects on the material macro properties. Key Features Consists of two parts: one exploring methods and theories and the other detailing related examples Defines stochastic defects in materials and presents the uncertainty quantification for defect location, size, geometrical configuration, and instability Introduces general Monte Carlo methods, polynomial chaos expansion, stochastic finite element methods, and machine learning methods Provides a variety of examples to support the introduced methods and theories Applicable to MATLAB® and ANSYS software This book is intended for advanced students interested in material defect quantification methods and material reliability assessment, researchers investigating artificial material microstructure optimization, and engineers working on defect influence analysis and nondestructive defect testing.
Since their discovery more than a decade ago, carbon nanotubes (CNTs) have held scientists and engineers in captive fascination, seated on the verge of enormous breakthroughs in areas such as medicine, electronics, and materials science, to name but a few. Taking a broad look at CNTs and the tools used to study them, Carbon Nanotubes: Properties and Applications comprises the efforts of leading nanotube researchers led by Michael O’Connell, protégé of the late father of nanotechnology, Richard Smalley. Each chapter is a self-contained treatise on various aspects of CNT synthesis, characterization, modification, and applications. The book opens with a general introduction to the basic characteristics and the history of CNTs, followed by discussions on synthesis methods and the growth of “peapod” structures. Coverage then moves to electronic properties and band structures of single-wall nanotubes (SWNTs), magnetic properties, Raman spectroscopy of electronic and chemical behavior, and electromechanical properties and applications in NEMS (nanoelectromechanical systems). Turning to applications, the final sections of the book explore mechanical properties of SWNTs spun into fibers, sidewall functionalization in composites, and using SWNTs as tips for scanning probe microscopes. Taking a fresh look at this burgeoning field, Carbon Nanotubes: Properties and Applications points the way toward making CNTs commercially viable.