Due to legal and consumer demands, eco-friendly resources that comply with environmental concerns while maintaining or improving performance are highly sought amongst manufacturers. Green materials are a specific material that are widely found in many product markets and are popular choices as alternative materials due to their recyclable, reusable, highly available, and corrosion-resistant features. These materials positively impact the environment through fewer emissions during the production process, positive carbon credits and energy recovery from incineration, and lower global warming effect. Extensive research is required to understand the full potential of these eco-friendly substances. Implementation and Evaluation of Green Materials in Technology Development: Emerging Research and Opportunities provides emerging research exploring the theoretical and practical aspects of environmentally friendly resources and applications within technology. Featuring coverage on a broad range of topics such as life cycle analysis, nanomaterials, and environment management, this book is ideally designed for manufacturers, engineers, product developers, industrial practitioners, policymakers, researchers, academicians, students, and business and marketing associates seeking current research on the advancements and applications of green materials in future technology.

The applications of biocomposite materials are increasing in aerospace, automobile, and household items due to their biodegradable, renewable, non-corrosion, and high strength to weight ratio properties. The processing and characterization of biofiber-reinforced biocomposite materials are vital for their strength and performance. This book discusses the properties, chemical treatment, and compatibility of biofibers with materials.

This book is the first volume in a two-volume compilation on controlled/living radical polymerization. It combines all important aspects of controlled radical polymerization: from synthetic procedures, to rational selection of reaction components, to understanding of the reaction mechanisms, to materials and applications.
This book is focused on recent progress in the rapidly developing field of controlled/living radical polymerization. It is a sequel to ACS Symposium Series 685, 768, 854, 944, 1023, and 1024. Volume 1100 deals with the mechanistic aspects of controlled radical polymerization and describes the recent advances in the most important techniques, whereas Volume 1101 contains chapters on new materials prepared by controlled radical polymerization as well as applications of these materials.

Nanodiamonds: Advanced Material Analysis, Properties and Applications illustrates the complementarity of specific techniques to fully characterize nanodiamonds from their diamond core (crystalline structure, defects, sp2 carbon, impurities, strain) to their surface (surface chemistry, stability of surface groups, reactivity, surface charge, colloidal properties). The relationship between physical and chemical parameters sits at the heart of what this book is about. Recent advances in the synthesis of nanodiamonds either by HPHT or detonation are covered, along with extended characterization of the core and surface of nanodiamonds, focusing on the most advanced experimental tools developed for nanoscale diagnosis. Each technique presented includes presentation of both principles and applications. This combination of advanced characterizations offers readers a better understanding of the relationship that exists between physical and chemical parameters of nanodiamonds and their properties. In particular, the role of structural defects or chemical impurities is illustrated. Toxicity of nanodiamonds for cells is also discussed, as It is an essential issue for their bioapplications. Final sections in the book cover the main promising new advances and applications of nanodiamonds, the formation of hybrids, and their use in polymer and oil composites.

This two volume set introduces the up-to-date high-tech applications of Aggregation-Induced Emission (AIE) luminogens in biosensing, bioimaging, and biomedicine. The 2nd volume presents the applications of AIE materials in biomedicine, including the utilizations in biomedical polymers, organic nanoprobes, photosensitizer, photothermal agents, AIEgens-based delivery systems, etc. It is an essential reference for materials scientists, chemists, physicists and biological chemists.

Strengthening of Concrete Structures Using Fiber Reinforced Polymers (FRP): Design, Construction and Practical Applications presents a best practice guide on the structural design and strengthening of bridge structures using advanced Fiber Reinforced Polymer (FRP) composites. The book briefly covers the basic concepts of FRP materials and composite mechanics, while focusing on practical design and construction issues, including inspection and quality control, paying special attention to the differences in various design codes (US, Japan, and Europe) and recommendations. At present, several design guides from the US, Japan, and Europe are available. These guidelines are often inconsistent and do not cover all necessary design and inspection issues to the same degree of detail. This book provides a critical review and comparison of these guidelines, and then puts forward best practice recommendations, filling a significant gap in the literature, and serving as an important resource for engineers, architects, academics, and students interested in FRP materials and their structural applications. Written from a practitioner's point-of-view, it is a valuable design book for structural engineers all over the world.

Defect Structure and Properties of Nanomaterials: Second and Extended Edition covers a wide range of nanomaterials including metals, alloys, ceramics, diamond, carbon nanotubes, and their composites. This new edition is fully revised and updated, covering important advances that have taken place in recent years. Nanostructured materials exhibit unique mechanical and physical properties compared with their coarse-grained counterparts, therefore these materials are currently a major focus in materials science. The production methods of nanomaterials affect the lattice defect structure (vacancies, dislocations, disclinations, stacking faults, twins, and grain boundaries) that has a major influence on their mechanical and physical properties. In this book, the production routes of nanomaterials are described in detail, and the relationships between the processing conditions and the resultant defect structure, as well as the defect-related properties (e.g. mechanical behavior, electrical resistance, diffusion, corrosion resistance, thermal stability, hydrogen storage capability, etc.) are reviewed. In particular, new processing methods of nanomaterials are described in the chapter dealing with the manufacturing procedures of nanostructured materials. New chapters on (i) the experimental methods for the study of lattice defects, (ii) the defect structure in nanodisperse particles, and (iii) the influence of lattice defects on electrical, corrosion, and diffusion properties are included, to further enhance what has become a leading reference for engineering, physics, and materials science audiences.

Rheology: Concepts, Methods and Applications, Third Edition provides a thorough historical and theoretical grounding in the field, and introduces rheology as the method of solving many practical problems in materials science and engineering. The book is practical and relevant for industry, but is also consistent with rheology courses in academia, making it relevant to both academics and accomplished rheologists in industry. The first four chapters discuss various aspects of theoretical rheology and, through examples from numerous studies, show how particular theories, models, or equations can be used in solving different problems. The shared experience and insight contained in these chapters assists practitioners carrying out rheological studies in generating relevant data. This helps to avert costly errors in analysis which are common when data are generated under the wrong conditions, or are incorrectly used. The fifth chapter covers methods of measurement and treatment of raw data-eight groups of methods are discussed in this chapter, providing the reader with many options for experimentation, along with guidance on where and how to use them properly. The final chapter demonstrates how to use rheological methods for different groups of products and manufacturing methods. The usefulness of chemorheological (rheokinetical) measurements is also emphasized. The chapter has a particular emphasis on real-world applications of rheology, and gives practical guidance to enable materials scientists to gather data and solve problems using these methods. This book is a systematic presentation of the subject of rheology-written by two of the foremost researchers in the field-showing the subject as an interrelated system of concepts, principal phenomena, experimental methods, and directions of their application. It also links with other branches of theoretical and applied sciences.

Recent agricultural, food, and pharmaceutical research focuses attention on the development of delivery systems that can encapsulate, protect, and deliver natural compounds. Nanoemulsions are recognized as the best delivery systems for natural-origin nutraceuticals and phytochemicals, having many agri-food applications. Bio-based Nanoemulsions for Agri-Food Applications provides information on food-grade nanoemulsions and their application in agriculture and the food industry. This book covers concepts, techniques, current advances, and challenges in the formulation of the application of emerging food grade nanoemulsions. Particular attention is placed on food-grade nanoemulsion production methods and components used, such as plant/microbial products, biosurfactants, cosurfactants, emulsifiers, ligand targets, and bioactive/functional ingredients. This is an important reference source for materials scientists, engineers and food scientists who are looking to understand how nanoemulsions are being used in the agri-food sector.

Silicon based materials and polymers are made of silicon containing polymers, mainly macromolecular siloxanes (silicones). This book covers the different kinds of siliconbased polymers: silicones, silsesquioxanes (POSS), and silicon-based copolymers. Other silicon containig polymers: polycarbosilanes, polysilazanes, siloxane-organic copolymers, silicon derived high-tech ceramics: silicon carbide and oxycarbide, silicon nitride, etc. have also a very important practical meaning and a hudge number of practical applications. These materials make up products in a variety of industries and products, including technical and medical applicatons. Polycrystalline silicon is the basic material for large scale photovoltaic (PV) applications as solar cells. Technical applications of crystalline (c-Si) and amorphous (a-Si) silicon (fully inorganic materials), silicon nanowires are still quickly growing, especially in the fi eld of microelectronics, optoelectronics, photonics. and photovoltaics, catalysts, and different electronic devices (e.g. sensors, thermoelectric devices). This book is ideal for researchers and as such covers the industrial perspective of using each class of silicon based materials. Discusses silanes, silane coupling agents (SCA), silica, silicates, silane modified fillers, silsesquioxanes, silicones, and other silicon polymers and copolymers for practical applications as polymeric materials and very useful ingredients in materials science.

Manufacturing processes have undergone significant developments in recent years. With the application of new technology, the productivity of companies has increased tremendously. 3D Printing and Its Impact on the Production of Fully Functional Components: Emerging Research and Opportunities is an innovative source of scholarly research on the advancements of 3D printing technology in modern manufacturing processes. Highlighting critical perspectives on topics such as industrial applications, 3D modeling, and bioprinting, this publication is ideally designed for professionals, academics, engineers, students, and practitioners interested in the latest trends in additive manufacturing.

Mechanical Behaviors of Carbon Nanotubes: Theoretical and Numerical Approaches presents various theoretical and numerical studies on mechanical behaviors of carbon nanotubes. The main theoretical aspects included in the book contain classical molecular dynamics simulation, atomistic-continuum theory, atomic finite element method, continuum plate, nonlocal continuum plate, and shell models. Detailed coverage is also given to structural and elastic properties, trace of large deformation, buckling and post-buckling behaviors, fracture, vibration characteristics, wave propagation, and the most promising engineering applications. This book not only illustrates the theoretical and numerical methods for analyzing the mechanical behavior of carbon nanotubes, but also contains computational results from experiments that have already taken place.

Encyclopedia of Materials: Plastics and Polymers, Four Volume Set covers plastics and polymeric materials, including their fundamental properties, current and potential future application areas in various private, public, commercial and industrial sectors, and their biodegradability, reusability and disposability. As well as covering all aspects of the science and applications of plastics and polymers, the book expounds on newer developments, including up-to-date articles and knowledge. In addition, the detrimental environmental effects of plastics and polymers are included, along with expertly-written articles that shed light on composites of macro, micro- and nano-particle sized plastic and polymeric materials and biodegradable natural or synthetic materials. This encyclopedia will be most valuable to researchers working at the interface between materials science/chemistry and materials engineering, as well as advanced undergraduates who need to quickly understand a broad range of foundational concepts and the developments that have taken place over time.

The world of nanomaterials is complex; there is dubiety as well as unrealistic optimism about costs, practicality, timing for the availability of, and the true capabilities of products featured in the news. The progress of the industry is being affected from the incertitude generated by the multitudinous names used, coupled with lack of clarity and standardization in the definitions for carbonaceous nanomaterials, such as graphene, graphene oxide, nanographene, nanographene flakes, nanographite flakes, graphene nanoribbons, single-layer graphene, few-layer graphene, nanographite, nanotubes, nanofibers. In this perspicuous book about the carbonaceous nanomaterial domain, the author concisely covers nomenclature, characteristics, applications, costs, and manufacturing; all with the cardinal goal to offer the reader a reality check by delineating the steps to commercialization. Along the way, he also examines the cost impact of the touted applications and the boundaries of market adoption. Through references and personal experience, the author makes a compelling case for the market readiness of a mostly neglected class of nanomaterials known as Graphitic Nanofibers. Includes varied levels of technical focus and financial analyses to appeal to a range of skills and interests.

Materials for Bone Disorders is written by a cross-disciplinary team of research scientists, engineers, and clinicians and bridges the gap between materials science and bone disorders, providing integrated coverage of biomaterials and their applications. The bioceramics, biopolymers, composites, and metallic materials used in the treatment of bone disorders are introduced, as are their interactions with cells, biomolecules, and body tissues. The main types of bone disorder and disease are covered including osteoporosis, spinal injury, load bearing joint diseases, bone cancer, and forms of cranio-maxillofacial disorders. Bone disorders are common across all ages. Various forms of bone disorders can change the lifestyle of otherwise normal and healthy people. With the development of novel materials, many forms of bone disorders are becoming manageable, allowing people to lead a fairly normal life. Specific consideration is given to areas where recent advances are enabling new treatments, such as the use of resorbable ceramics in bone tissue engineering and drug delivery, newer polymer-based implants in load-bearing contexts, and engineering biomaterials surfaces including modifying surface chemistry. Ethical and regulatory issues are also explored.

Metallic Foam Bone: Processing, Modification and Characterization and Properties examines the use of porous metals as novel bone replacement materials. With a strong focus on materials science and clinical applications, the book also examines the modification of metals to ensure their biocompatibility and efficacy in vivo. Initial chapters discuss processing and production methods of metals for tissue engineering and biomedical applications that are followed by topics on practical applications in orthopedics and dentistry. Finally, the book addresses the surface science of metallic foam and how it can be tailored for medical applications. This book is a valuable resource for materials scientists, biomedical engineers, and clinicians with an interest in innovative biomaterials for orthopedic and bone restoration.

Progress in Rubber Nanocomposites provides an up-to-date review on the latest advances and developments in the field of rubber nanocomposites. It is intended to serve as a one-stop reference resource to showcase important research accomplishments in the area of rubber nanocomposites, with particular emphasis on the use of nanofillers. Chapters discuss major progress in the field and provide scope for further developments that will have an impact in the industrial research area. Global leaders and researchers from industry, academia, government, and private research institutions contribute valuable information.