Design and Fabrication of Large Polymer Constructions in Space is a ground-breaking study of the polymeric materials, advanced chemical processes, and cutting-edge technology required in the construction of large polymer-based structures for space, when all steps in the process are carried out in the space environment, whether in orbit, in deep space, or on the surface of a moon, asteroid, or planet. The book begins by introducing the fundamentals and requirements of large constructions and inflatable structures for space. The next section of the book focuses on the utilization of polymeric materials within the space environment, examining the effects on materials (vacuum, plasma, temperature), the possible approaches to polymerization both in space and in orbit, the preparation and structure of polymer composites, and the methods for testing materials and structures in terms of strength, defects, and aging. Three chapters then cover how these materials and techniques might be applied to specific categories of construction, including larger space habitats, supporting space structures, and ground infrastructure. Finally, the financial aspects, the consequences for human space exploitation, and the possible future developments are discussed. Using materials science to push the boundaries of construction for space exploration and exploitation, this book is a unique resource for academic researchers and advanced students across polymer science, advanced materials, chemical engineering, construction, and space engineering, as well as for researchers, scientists and engineers at space agencies, companies and laboratories, involved in developing materials or technology for use in space. This is also of great interest to anyone interested in the role of materials science in the building of large space stations, spacecraft, planetary bases, large aperture antenna, radiation and thermal shields, and repairmen sets.

Polymeric materials offer a high level of versatility due to the range of applications possible within the biomedical and clinical fields - including wound closure - particularly in comparison to metals or ceramics. These specialised materials also allow for a diverse array of therapeutic effects. Although there have been advances in improving polymeric materials for surgical sutures, there is little information available regarding improving the therapeutic value of sutures, and advanced technologies used to implement this improvement. Advanced Technologies and Polymer Materials for Surgical Sutures provides thorough coverage on suture materials with improved mechanical and therapeutic properties that can improve quality of life; chapter topics include drug-releasing kinetics of sutures, shape memory polymer sutures and future trends. This book is a useful resource for academics and researchers in the materials science and biomedical engineering fields, as well as professionals in biomaterials and biotextiles development and clinicians looking to learn more about suture material properties and suture/body interactions.

Reliability and Failure Analysis of High-Power LED Packaging provides fundamental understanding of the reliability and failure analysis of materials for high-power LED packaging, with the ultimate goal of enabling new packaging materials. This book describes the limitations of the present reliability standards in determining the lifetime of high-power LEDs due to the lack of deep understanding of the packaging materials and their interaction with each other. Many new failure mechanisms are investigated and presented with consideration of the different stresses imposed by varying environmental conditions. The detailed failure mechanisms are unique to this book and will provide insights for readers regarding the possible failure mechanisms in high-power LEDs. The authors also show the importance of simulation in understanding the hidden failure mechanisms in LEDs. Along with simulation, the use of various destructive and non-destructive tools such as C-SAM, SEM, FTIR, Optical Microscopy, etc. in investigation of the causes of LED failures are reviewed. The advancement of LEDs in the last two decades has opened vast new applications for LEDs which also has led to harsher stress conditions for high-power LEDs. Thus, existing standards and reliability tests need to be revised to meet the new demands for high-power LEDs.

Aptamers Engineered Nanocarriers for Cancer Therapy details the selection technologies, biological characteristics, and clinical uses of aptamer-based nano agents for cancer therapeutics. The book helps facilitate speedy solutions for some of the problems pertaining to the manufacture of nano-aptamers - such as toxicity, thermal stability, cost efficiency, tumor penetration and blood stability. Key chapters cover cell-SELEX technology for aptamer selection, mechanisms of multi-drug resistance of cancer, the relevance of aptamers as anticancer therapies, as well as the broad range of aptamer-functionalized nanostructures available. This book provides exciting insights into this relatively new approach to cancer therapeutics, and will be of interest to materials scientists, biomedical engineers, molecular biologists, biochemists and clinical scientists, with a focus on cancer therapy.

Protein-Based Biopolymers: From Source to Biomedical Applications provides an overview on the development and application of protein biopolymers in biomedicine. Protein polymers have garnered increasing focus in the development of biomedical materials, devices and therapeutics due to their intrinsic bioactivity, biocompatibility and biodegradability. This book comprehensively reviews the latest advances on the synthesis, characterization, properties and applications of protein-based biopolymers. Each chapter is dedicated to a single protein class, covering a broad range of proteins including silk, collagen, keratin, fibrin, and more. In addition, the book explores the biomedical potential of these polymers, from tissue engineering, to drug delivery and wound healing. This book offers a valuable resource for academics and researchers in the fields of materials science, biomedical engineering and R&D groups working in pharmaceutical and biomedical industries.

Modern Ion Plating Technology: Fundamentals and Applications discusses the fundamental concepts of plasma physics in various coating technologies and explores its development and implementation into new technologies. Recent progress of technologies and products via ion plating will be introduced. The book begins with the treatment of vacuum physics, through plasma physics. It then presents the various forms of ion plating, before concluding with a section presenting examples of applications where ion plating is employed. Through the material presented in this book, the reader gains an understanding of the importance of ion plating technology to human progress and its various potential applications. Under the guidance of plasma physics knowledge, how to use electric and electromagnetic fields to control the space plasma will be critical to the development of new technology and systems.

Smart Nanomaterials for Bioencapsulation focuses on the fundamentals, synthesis methods and matrix design for the encapsulation of drugs, drug release, food and nutraceuticals, mechanisms of nano- encapsulated drugs on liposomes, micelles, silica composites, carbon nanotubes, dendrimers, and protein inorganic nanohybrids. Providing detailed information on the encapsulation of food and drug derivatives, the book helps create new and modern approaches for both pharmaceutical and nutritional science. The target delivery of pharmacological agents, as well as food additives under various conditions is covered, including sections on systemic release of drug molecules, minimum loss at non-target sites, the accumulation of diseased tissue or organs, and more. Smart nanomaterial-based nanocarriers protect the loaded molecules from premature degradation in the biological environment and enhance bioavailability for cellular uptake. The tuned properties of smart nanomaterials, such as porosity, pore-volume, surface area-to-volume ratio, coating with inert and labile materials, and more help determine the in vivo performance of the bioencapsulated food and drug derivatives.

Nano-scale materials have unique electronic, optical, and chemical properties that make them attractive for a new generation of devices. In the second edition of Modeling, Characterization, and Production of Nanomaterials: Electronics, Photonics, and Energy Applications, leading experts review the latest advances in research in the understanding, prediction, and methods of production of current and emerging nanomaterials for key applications. The chapters in the first half of the book cover applications of different modeling techniques, such as Green's function-based multiscale modeling and density functional theory, to simulate nanomaterials and their structures, properties, and devices. The chapters in the second half describe the characterization of nanomaterials using advanced material characterization techniques, such as high-resolution electron microscopy, near-field scanning microwave microscopy, confocal micro-Raman spectroscopy, thermal analysis of nanoparticles, and applications of nanomaterials in areas such as electronics, solar energy, catalysis, and sensing. The second edition includes emerging relevant nanomaterials, applications, and updated modeling and characterization techniques and new understanding of nanomaterials.

Fretting Wear and Fretting Fatigue: Fundamental Principles and Applications takes a combined mechanics and materials approach, providing readers with a fundamental understanding of fretting phenomena, related modeling and experimentation techniques, methods for mitigation, and robust examples of practical applications across an array of engineering disciplines. Sections cover the underpinning theories of fretting wear and fretting fatigue, delve into experimentation and modeling methods, and cover a broad array of applications of fretting fatigue and fretting wear, looking at its impacts in medical implants, suspension ropes, bearings, heating exchangers, electrical connectors, and more.

2D Materials for Electronics, Sensors and Devices: Synthesis, Characterization, Fabrication and Application provides an overview of various top-down and bottom-up synthesis techniques, along with stitching, stacking and stoichiometric control methods for different 2D materials and their heterostructures. The book focuses on the widespread applications of various 2D materials in high-performance and low-power sensors, field effect devices, flexible electronics, straintronics, spintronics, brain-inspired electronics, energy harvesting and energy storage devices. This is an important reference for materials scientists and engineers looking to gain a greater understanding on how 2D materials are being used to create a range of low cost, sustainable products and devices.

Synthesis, Characterization and Applications of Graphitic Carbon Nitride: An Uprising Carbonaceous Material offers an up-to-date record on the major findings and observations relating to graphitic carbon nitride-based systems, elaborately covering all the aspects of carbon nitride as chemical stable and pollution-free materials that are easy to prepare in a cost-effective way, along with their applications in photocatalytic degradation of pollutants, photocatalytic hydrogen generation, carbon dioxide reduction, disinfection, sensors and supercapacitors. Graphitic carbon nitride (g-C3N4) is a fascinating visible light photocatalyst, which possesses many properties that can be used for many applications. This makes the book an indispensable reference for (post)-graduate students, researchers in academia and industry, and engineers working in the field of graphitic carbon-nitride-based systems.

Dynamic Deformation, Damage and Fracture in Composite Materials and Structures, Second Edition reviews various aspects of dynamic deformation, damage and fracture, mostly in composite laminates and sandwich structures, and in a broad range of application areas including aerospace, automotive, defense and sports engineering. This book examines low- and high-velocity loading and assesses shock, blast and penetrative events, and has been updated to cover important new developments such as the use of additive manufacturing to produce composites, including fiber-reinforced ones. New microstructural, experimental, theoretical, and numerical studies with advanced tools are included as well. The book also features four new chapters covering topics such as dynamic delamination, dynamic deformation and fracture in 3D-printed composites, ballistic impacts with fragmenting projectiles, and the effect of multiple impacting.

Functionalized Carbon Nanomaterials for Theranostic Applications offers insights into the developments and trends that are progressing fast in the field of functionalized carbon nanomaterials-based devices as diagnostic tools for early stage detection of human diseases. The book provides information on how functionalized carbon nanomaterials are being used as the basis for products, such as early disease diagnostic kits, quantum dots for medical imaging and a growing list of other applications. Sections cover different mechanical, absorption, optical and electrical properties than those found in original nanomaterials. This is an important reference source that will be valuable to materials scientists, biomedical engineers and pharmaceutical scientists who are looking to increase their understanding on how functionalized carbon nanomaterials are being used for a variety of theranostic applications.

Advances in Biomedical Polymers and Composites: Materials and Applications is a comprehensive guide to polymers and polymer composites for biomedical applications, bringing together detailed information on their preparation, properties, cutting-edge technologies, innovative materials and key application areas. Sections introduce polymers and composites in biomedical applications and cover characterization techniques, preparation and properties of composites and gel-based systems. Innovative technologies and instruments used in the fabrication of polymer composites for biomedical applications are then presented in detail, including 3D bioprinting, 4D printing, electrospinning, stimuli-responsive polymers and quantum dots. This is a valuable resource for anyone looking to gain a broader understanding of polymers and composites for biomedical applications. In addition, it is ideal for readers who want to conduct interdisciplinary research or explore new avenues for research and development.

Biodegradability of Conventional Plastics: Opportunities, Challenges, and Misconceptions brings together innovative research on the biodegradability of conventional plastics, providing an extensive overview of approaches and strategies that may be implemented, while also highlighting other methods for alleviating the eventual environmental impact of plastics. The book begins by providing a lifecycle assessment of plastics, the environmental impact of plastic waste, and the factors that affect the biodegradability of plastics. The different categories and terminologies surrounding bio-based plastics and biodegradable plastics are then defined and explained in detail, as are the issues surrounding bioplastics. Other sections discuss biodegradability, approaches for enhanced biodegradability of various major types of plastics, including polyolefins, polyethylene terephthalate (PET), polystyrene, poly(vinyl chloride), automotive plastics and composites, and agricultural plastic waste. The final part of the book focuses on further techniques and emerging areas, including the utilization of chemical additives, nanomaterials, the role of microbes in terms of microbial degradation and microbial attaching, revalorization of plastic waste through industrial biotechnology, and future opportunities and challenges.

Design and Applications of Theranostic Nanomedicines reviews the composition and design of various nanomedicines for theranostic applications, helping readers to make informed decisions when exploring novel treatments for disease. This book introduces readers to theranostic nanostructures as nanomedicines, beginning with a balanced look at the associated challenges, costs and benefits. The next section goes on to detail a range of different theranostic nanomedicines and their design, from nanodispersions and nanogels to exosomes and polymeric micelles. A variety of applications is covered, including in the treatment of pulmonary diseases, neurological disorders, cancers and more. The book also takes a look at the toxicological implications of nanotheranostics, an important aspect of any therapy or treatment. Design and Applications of Theranostic Nanomedicines provides a snapshot of the state-of-the-art, and will be of use to materials scientists, biomedical engineers and pharmaceutical scientists with an interest in nanotechnology and theranostics.

Hydrodynamic Lubrication of Non-Newtonian Fluids covers basic theory, lubrication failure and numerical methods and procedures. The title offers a feasible method for solving the hydrodynamic lubrication problem for non-Newtonian fluids. Whereas hydrodynamic lubrication in Newtonian fluids can be solved using the existing Reynolds equation, hydrodynamic lubrication in non-Newtonian fluid is much more difficult to solve because the non-Newtonian constitutive equation is nonlinear. Engineers and technicians working on non-Newtonian fluid lubrication calculation and analysis will find this to be an invaluable reference on the latest thinking on hydrodynamic lubrication. This book presents a unified solution to hydrodynamic lubrication in non-Newtonian fluids, proposing a flow separation method. In addition, the title gives methods and insights into viscosity in non-Newtonian fluids, the lubrication failure mechanism and fluid lubrication mechanism carrying capacity.

Plastics and Sustainability: Practical Approaches provides a broad overview of sustainability as applied to plastics, offering a range of opportunities and solutions to be applied in an academic or industrial setting. The book begins by introducing the challenges and opportunities relating to plastics and environmental sustainability. This is followed by detailed eco-profiles organized by polymer category. Subsequent chapters explore various approaches to plastics sustainability, with in-depth coverage of incineration technology for energy recovery, pyrolysis for chemical recovery, blending technology, design, packaging, circular economy, and biopolymers. Finally, international policies are summarized. The book aims to provide a broad source of information and a range of options to readers on how to evaluate and improve the sustainability of plastics, with analyses of the advantages and drawbacks of different technologies and materials. Authored by two professional engineers with substantial experience in industry and consultancy, this is a valuable resource for all those looking for a wide-ranging overview of sustainability as applied to plastics, including researchers and advanced students from a range of materials science and engineering disciplines, and engineers, manufacturers, scientists, and R&D professionals from a range of industries.

Engineered Nanostructures for Therapeutics and Biomedical Applications offers a single reference for a diverse biomedical readership to learn about the application of nanotechnology in biomedicine and biomedical engineering, from past developments to current research and future prospects. This book sets out a broad selection of biomedical and therapeutic applications for nanostructures, including bioimaging, nanorobotics, orthopedics, and tissue engineering, offering a useful, multidisciplinary approach. Each chapter discusses challenges faced in each discipline, including limiting factors, biocompatibility, and toxicity, thus enabling the reader to make informed decisions in their research. This book is a comprehensive, broad overview of the role and significance of nanomaterials and their composites that also includes discussions of key aspects in the field of biomedicine. It will be of significant interest to academics and researchers in materials science and engineering, biomedicine and biomedical engineering, chemical engineering, pharmaceutics, bioimaging, and nanorobotics.

Fused Deposition Modeling of Composite Materials is dedicated to the field of 3D-printing of composite materials using a popular technique called Fused Deposition Modeling (FDM), the world's most popular 3D printing method. But this method is currently limited to printing basic polymers and only a handful of primitive composite materials. Many future industries, such as Space, Biomed, Construction and Defense are waiting for the ability to 3D print composites and new functional materials with complex shapes and features so they can add unique and customizable features to their parts, including biocompatibility, radiation shielding, high-strength, rapid cooling, flexibility and shape-memory. The book's authors take the reader through the basics of what the FDM technique is all about and describe the advantages and new opportunities arising from 3D printing innovative materials, which include polymer-matrix composites and fully inorganic parts. They then review and discuss methods for making the different types of composite feedstock filaments needed to 3D print such materials by FDM. Finally, sections discuss the challenges that should be considered in making filaments and parts and how to go about solving them.

Carbon Dots in Analytical Chemistry: Detection and Imaging explores recent progress in the field of carbon dots synthesis and properties and their integration with various miniaturized analytical devices for the detection of chemical species and imaging of cells. This book is dedicated to exploring the potential applications of carbon dots in analytical chemistry for clinical microbiology, pharmaceutical analysis and environmental analysis. Sections cover synthetic approaches and properties, sample preparation, analytical techniques for the detection of chemical species, imaging of molecules and cells, and analytical tools for biomedical and food analysis. The will be a valuable book for analytical and materials scientists, physical and chemical scientists, and engineers investigating the use of carbon nanomaterials in their analytical procedures.

Metallic Glasses and Their Oxidation provides a comprehensive review of the structures, properties, preparations, processing and applications of metallic glasses. Special attention is paid to the oxidation behaviors and related mechanisms of metallic glasses that occur during their preparation, processing and application. The book's authors introduce basic knowledge of metallic glasses, including their structures, properties, processing techniques and applications. Then, the theories and techniques commonly used in oxidation investigation are highlighted, including thermal oxidation, native oxidation, stressed oxidation, powder oxidation and oxidation simulation. The book closes with the influence of oxidation on the structures and performances of metallic glasses, proposes measures to control oxidation, and discusses how to take advantage of oxidation to reinforce materials or create new materials.