Advances in Nonlinear Photonics combines fundamental principles with an overview of the latest developments. The book is suitable for the multidisciplinary audience of photonics researchers and practitioners in academia and R&D, including materials scientists and engineers, applied physicists, chemists, etc. As nonlinear phenomena are at the core of photonic devices and may enable future applications such as all-optical switching, all-optical signal processing and quantum photonics, this book provides an overview of key concepts. In addition, the book reviews the most important advances in the field and how nonlinear processes may be exploited in different photonic applications.

AI-based technologies and, in a broader sense, digital technologies have become very important in civil engineering design. Artificial Intelligence-Based Design of Reinforced Concrete Structures: Artificial Neural Networks for Engineering Applications is an essential reference resource for those readers who want to learn how to perform artificial intelligence-based structural design. The book describes in detail the main concepts of ANNs and their application and use in civil and architectural engineering. It shows how neural networks can be established and implemented depending on the nature of a broad range of diverse engineering problems. The design examples include both civil and architectural engineering solutions, for both structural engineering and concrete structures. Those who have not had the opportunity to study or implement neural networks before will find this book very easy to follow. It covers the basic network theory and how to formulate and apply neural networks to real-world problems. There are plenty of examples based on real engineering problems and solutions.

Polymer-Based Nanoscale Materials for Surface Coatings presents the latest advances and emerging technologies in polymer-based nanomaterials for coatings, focusing on novel materials, characterization techniques, and cutting-edge applications. Sections present the fundamentals of surface preparation and nanocoatings, linking materials and properties, explaining the correlation between morphology, surface phenomena, and surface protection mechanism, and covering theory, modeling and simulation. Other presented topics cover characterization methods, with an emphasis on the latest developments in techniques and approaches. Aging and lifecycle assessment of coated surfaces and coatings are also discussed. Final sections explore advanced applications across a range of fields, including intelligent coatings for biomedical implants, self-healing coatings, syper-hydrophobicity, electroluminescence, sustainable edible coatings, marine antifouling, corrosion resistance, and photocatalytic coatings.

Advanced Fluoropolymer Nanocomposites: Fabrication, Processing, Characterization and Applications presents a comprehensive review on the fundamental chemistry, physics, biology and engineering of advanced fluoropolymer nanocomposites. Detailed attention is given to the synthesis, processing characterization, properties and applications of fluoropolymer nanocomposites. Morphological, thermal, electrical, mechanical, tribological and viscoelastic properties are also discussed in detail, along with the influence of synthesis methods on the formation of fluoropolymer nanocomposites, including the effect of nanofiller size and shape and the dispersion state of various nanofillers in different fluoropolymer matrices. This book will be a useful reference resource for scientists, engineers and postgraduate students working in the field of polymer science and technology, materials science and engineering, composites and nanocomposites. This resource will help them find solutions to both fundamental and applied problems associated with their research. It will also assist researchers in becoming more acquainted with the field to address key questions within a short time.

Polymers in Electronics: Optoelectronic Properties, Design, Fabrication, and Applications brings together the fundamentals and latest advances in polymeric materials for electronic device applications, supporting researchers, scientists and advanced students, and approaching the topic from a range of disciplines. The book begins by introducing polymeric materials, their dielectric, optical, and thermal properties, and the essential principles and techniques for polymers as applied to electronics. This is followed by detailed coverage of the key steps in the preparation of polymeric materials for opto-electronic devices, including fabrication methods, materials design, rheology, encapsulation, and conductive polymer mechanisms. The final part of the book focuses on the latest developments in advanced devices, covering the areas of photovoltaics, transistors, light-emitting diodes, and stretchable electronics. In addition, it explains mechanisms, design, fabrication techniques, and end applications. This is a highly valuable resource for researchers, advanced students, engineers and R&D professionals from a range of disciplines.

Nanomaterials for Bioreactors and Bioprocessing Applications explores the potential of nanomaterials in improving the efficiency of bioprocessing industries and next-generation bioreactors. The book provides information on various newly synthesized nanomaterials in bioreactors for scaling up the bioprocess to an industrial level, the criteria and properties of nanomaterials to be used in bioprocessing, advantages, challenges while using the nanomaterials, and the economic constraints. In addition, the book also discusses the fate of various nanomaterials in the bioprocess, the chances of product contamination and its prevention. This book is an important reference source for materials scientists and biomedical engineers information on the synthesized nanomaterials that are available for bioreactors and bioprocesses, and the various optimized conditions and precautions to be taken.

Nanomedicine: Technologies and Applications, Second Edition provides an important review of this exciting technology and its growing range of applications. In this new edition, all chapters are thoroughly updated and revised, with new content on antibacterial technologies and green nanomedicine. Sections introduce the material, cover their properties, review nanomedicine for therapeutics, imaging and soft tissue engineering, including organ regeneration, skin grafts, nanotubes and self-assembled nanomaterials. Other sections cover bone and cartilage tissue engineering, nanostructured particles for antibacterial purposes, advances in green nanomedicine, and using natural nanomedicine to fight disease. This book is an indispensable guide for all those involved in the research, development and application of this exciting technology, whilst also providing a comprehensive introduction for students and academics interested in this field.

Graphene Based Biomolecular Electronic Devices outlines the fundamental concepts related to graphene and electronics, along with a description of various advanced and emerging applications of graphene-based bioelectronics. The book includes coverage of biosensors, energy storage devices such as biofuel cells, stretchable and flexible electronics, drug delivery systems, tissue engineering, and 3D printed graphene in bioelectronics. Taking an interdisciplinary approach, it explores the synergy produced due to charge transfer between biomolecules and graphene and will help the reader understand the promising bioelectronic applications of graphene-based devices. Graphene has applications in semiconductor electronics, replacing the use of traditional silicon-based devices due to its semi-metallic nature and tuneable energy band gap properties. The tuning of electron transfer with redox properties of biomolecules could potentially lead to the development of miniaturized bioelectronic devices. Thus, graphene, with its unique sensing characteristics, has emerged as an attractive material to produce biomolecular electronic devices.

Graphene Quantum Dots: Biomedical and Environmental Sustainability Applications provides an overview of fundamentals and advances in applications of graphene quantum dots. Concepts covered include a brief introduction on the topic, an overview of structure and chemistry, fundamental properties of different characterization techniques, methods for the preparation of graphene quantum dots, and recent and emerging applications in various fields including antimicrobial therapy, bioimaging, biomedical tools development and clean energy for environmental sustainability. The book is a critical resource in materials selection for biomedical and environmental sustainability applications as well as various advanced imaging, disinfectant and environmental remediation technologies. As such, it is suitable for those in academia working in the discipline of materials science and engineering and practitioners working on biomedical tool development and environmental remediation.

Circularity of Plastics: Sustainability, Emerging Materials, and Valorization of Waste Plastic takes an innovative, interdisciplinary approach to circularity and sustainability in plastics, with an emphasis on plastic waste and end-of-life treatment and options for recycling, re-use, valorization and development of biomass-based polymers. The book introduces key concepts of sustainable materials, the circular economy, and lifecycle assessment, and discusses challenges in the valorization of waste. Other sections cover the upcycling of waste plastic into new materials and fuels, with dedicated chapters exploring state-of-the-art techniques for conversion to new sustainable polymers, fuel, fine chemicals and carbon nanomaterials. Emerging technologies used to produce functional polymers from renewable feedstocks, including CO2, biomass, natural polymers, polylactic acid (PLA), and polyhydroxyalkanoate-based materials (PHAs) are then explored, with a final chapter focusing on applications of sustainable materials, challenges, and future perspectives. This is a valuable resource for researchers, scientists, engineers, R&D professionals, and advanced students from a range of disciplines and backgrounds, with an interest in sustainable materials, circularity in plastics, and polymer waste and valorization.

Fabrication and Functionalization of Advanced Tubular Nanofibers and their Applications describes the synthesis, preparation and characterization of carbon-based tubular nanofibers and their applications in environmental protection and new energy sources. The book explores novel strategies for the preparation of carbon tubular nanofibers and explains how they have been used to great effect in a range of applications, including energy and healthcare. The processing-structure-property relationship in functional inorganic/organic materials is examined at the nano-level, explaining where interesting electronic, magnetic, optical, mechanical or catalytic and therapeutic properties are derived. Covering everything from the basics to their use in practice, including the synthetic procedure and characterization, this book is the perfect guide for anyone interested in the design of nanomaterials for advanced applications. Nanomaterial science is a relatively young and rapidly developing discipline that includes aspects of physics, chemistry and biology and is finding applications in some of mankind's greatest current challenges.

Handbook of Thermoplastic Fluoropolymers: Properties, Characteristics and Data gathers key technical information about structure, characteristics, properties and processing methods of commercial thermoplastic fluoropolymers in one easy reference. Thermoplastic fluoropolymers have many desirable functional characteristics, such as high thermal stability, reliability at high mechanical loads, a wide range of operating temperatures, and high chemical and radiation stability. These characteristics make them crucial in many specialist applications, including in the military, biopharmaceuticals and environmental protection. This uniquely comprehensive guide to this versatile family of polymers will help processors, fabricators and end-users find new and innovative solutions. Detailed coverage of technical details of processing methods, characteristics, and chemical properties of commercial thermoplastic fluoropolymers all in one place make this the most authoritative reference to the subject available.

Protein-based Nanocomposites for Tissue Engineering details the design, development, efficacy and tissue engineering applications of a range of protein-based nanocomposite materials. Protein-based nanocomposites offer advantageous properties in that they are biodegradable, biocompatible, nonantigenic, highly stable and possess strong binding capacity. These unique properties make protein-based nanocomposite carriers promising candidates for controlled cell delivery in tissue engineering. This book covers a selection of protein types in their nanocomposite form, from albumin and keratin to collagen and silk. Each protein nanocomposite is described in detail, exploring their application in cell delivery and tissue engineering. The design, development, properties and molecular mechanism of protein-based nanocomposites is thoroughly discussed before going on to analyze the advantages and limitations of these useful materials, making this book an ideal resource for readers who want to explore biocompatible and naturally derived material options for tissue engineering applications. Academics and researchers in the fields of materials science, biomedical engineering, regenerative medicine and nanotechnology will find the book a must have.

Ferrite Nanostructured Magnetic Materials: Technologies and Applications provides detailed descriptions of the physical properties of ferrite nanoparticles and thin films. Synthesis methods and their applications in numerous fields are also included. And, since characterization methods play an important role in investigating the materials’ phenomena, various characterization tools applied to ferrite materials are also discussed. To meet the requirements of next-generation characterization tools in the field of ferrite research, synchrotron radiation-based spectroscopic and imaging tools are thoroughly explored. Finally, the book discusses current and emerging applications of ferrite nanostructured materials in industry, health, catalytic and environmental fields, making this comprehensive resource suitable for researchers and practitioners in the disciplines of materials science and engineering, chemistry and physics.

Biopolymers: Synthesis, Properties, and Emerging Applications presents the state-of-the-art in biopolymers, bringing together detailed information on synthesis strategies, processing and cutting-edge applications. The book begins by introducing the synthesis, processing and structural and functional properties of smart biopolymers and bionanocomposites. Subsequent chapters focus on the synthesis and preparation of biopolymers with valuable properties or for specific advanced applications, including piezoelectric properties, shape memory properties, biodegradable polymer blends, synthesis and assembly of nanomaterials, synthesis of green biopolymers, and catalytic synthesis of bio-sourced polyesters and polycarbonate, as well as applications in active food packaging, water purification, biomedicine, 3D printing, and automotive. Throughout the book, there are analyses of different synthesis strategies and processing methods and their role and use in different fields of application, whilst the important challenges relating to scalable processing and shaping and micro and nano structuration are also discussed. The book also strives to balance the synthetic aspects of biopolymers with physical principles, highlighting biopolymer-based architectures including composite or hybrid conjugates, providing in-depth discussion of important examples of reaction mechanisms, and exploring potential applications of biopolymer and conjugates, ranging from physical to chemical and biological systems.

Principles of Human Organs-on-Chips covers all aspects of microfluidic organ-on-a-chip systems, from fabrication to application and commercialization. Organ-on-a-chip models are created to mimic the structural, microenvironmental and physiological functions of human organs, providing the potential to bypass some cell and animal testing methods. This is a useful platform with widespread applications, frequently in drug screening and pathological studies. This book offers a comprehensive and authoritative reference on microfluidic organs-on-chips, spanning all key aspects from fabrication methods, cell culture systems and cell-based analysis, to dedicated chapters on specific tissue types and their associated organ-on-a-chip models, as well as their use as disease models, drug screening platforms and more. Principles of Human Organs-on-Chips helps materials scientists and biomedical engineers to better understand the specific requirements and challenges in the design and fabrication of organ-on-a-chip devices. This book also bridges the knowledge gap between medical device design and subsequent clinical applications, allowing medical professionals to easily learn about related engineering concepts and techniques.

Phytochemical Nanodelivery Systems as Potential Biopharmaceuticals comprehensively reviews current information on nanotechnology applied to phytochemical nanoencapsulation to enhance their bioavailability and bioactivity. The book is divided into two sections, the first section critically reviews current information on the field of nanotechnology and phytochemicals, and the second section highlights the pre-clinical and clinical studies of phytochemicals to comprehensively review the efficacy of these molecules as drugs of human use. Phytochemical Nanodelivery Systems as Potential Biopharmaceuticals provides a useful overview of this rapidly evolving field for materials scientists and pharmaceutical scientists, as well as for those with an interest in biopharmaceuticals from plant sources, such as organic chemists and food scientists.

ELEMENTS OF AERODYNAMICS An accessible and hands-on textbook filled with chapter objectives, examples, practice problems, sample tests, and an online aero-calculator In Elements of Aerodynamics, Professor Oscar Biblarz delivers a concise and fundamentals-oriented approach to aerodynamics suitable for both undergraduate and graduate-level students. The text offers numerous problems, examples, and check tests, allowing readers to gain and cement their knowledge through hands-on practice. Using a unique blend of fundamentals, the book provides students with a new approach to high lift airfoils including examples designed to complement the theory. It covers the most vital information on incompressible and compressible flow over two-dimensional and three-dimensional wings. A companion website that includes an interactive aero-calculator and additional student resources makes this a suitable text for online, hybrid, and distance learning. Readers will also find: A concise introduction to units and notation with discussion of the proper usage of dimensionless coefficients in aerodynamics, featuring descriptions of airflow as an incompressible and compressible low-viscosity medium past streamlined wings Comprehensive re-evaluation of the fundamentals of fluid dynamics, including the differential control volume approach and formulation of lift, drag, and pitching moments for thin, attached boundary layers over slender wings at high angles of attack Practical applications of mass, momentum, and energy relations, derived from Euler's equation, Bernoulli's equation, and the Kutta-Joukowski theorem Selected treatment of transonic and hypersonic aerodynamic aspects, including supercritical airfoils, the non-linear small perturbation potential equation, Newtonian theory, and hypersonic lift and drag Well-suited for students enrolled in an introductory aerodynamics course as part of an engineering program, Elements of Aerodynamics will also earn a place in the libraries of physics students and those interested in basic fluid mechanics.

Integrated Silicon-Metal Systems at the Nanoscale: Applications in Photonics, Quantum Computing, Networking, and Internet is a comprehensive guide to the interaction, materials, and functional integration at the nanoscale, of the silicon-metal binary system and a variety of emerging and next-generation advanced device applications, from energy and electronics, to sensing, to quantum computing and quantum internet networks. The book guides the readers through advanced techniques and etching processes, combining underlying principles, materials science, design, and operation of metal-Si nanodevices. Each chapter focuses on a specific use of integrated metal-silicon nanostructures, including storage and resistive next-generation nano memory and transistors, photo and molecular sensing, harvest and storage device electrodes, phosphor light converters, and hydrogen fuel cells, as well as future application areas, such as spin transistors, quantum computing, hybrid quantum devices, and quantum engineering, networking, and internet. This is a valuable resource for researchers and advanced students in nanomaterials and nanotechnology, electronics engineering, quantum computing, physics, and materials engineering, as well as for materials engineers, industrial scientists, and R&D professionals with an interest in silicon-metal nanodevices for state-of-the-art applications.

Biodegradable and Biocompatible Polymer Nanocomposites: Processing, Characterization, and Applications brings together the latest research, highlighting cutting-edge applications in this exciting field. Sections introduce biodegradable and biocompatible polymers and the fundamentals regarding synthesis, structure, properties, biocompatibility and biodegradability, provide in-depth coverage of methods and techniques for processing, spectroscopic and microscopic analysis, dielectric, thermal, and electrical conductivity, and incorporation of functionalized nanoparticles, and green synthesized nanoparticles. The second part of the book guides the reader through the properties and preparation of biodegradable and biocompatible polymer nanocomposites for a range of specific, targeted, state-of-the-art applications across biomedicine, electronic, energy storage, environment and packaging. Finally, sustainability assessment, environmental impact, and recycling strategies are discussed in detail.

Numerical Modeling of Nanoparticle Transport in Porous Media MATLAB/PYTHON Approach Focuses on modeling and numerical aspects of nanoparticle transport within single- and two-phase flow in porous media. The book discusses modeling development, dimensional analysis, numerical solutions and convergence analysis. Actual types of porous media have been considered, including heterogeneous, fractured, and anisotropic. Moreover, different interactions with nanoparticles are studied, such as magnetic nanoparticles, ferrofluids and polymers. Finally, several machine learning techniques are implemented to predict nanoparticle transport in porous media. This book provides a complete full reference in mathematical modeling and numerical aspects of nanoparticle transport in porous media. It is an important reference source for engineers, mathematicians, and materials scientists who are looking to increase their understanding of modeling, simulation, and analysis at the nanoscale.

Laser Additive Manufacturing of Metallic Materials and Components discusses the current state and future development of laser additive manufacturing technologies, detailing material, structure, process and performance. The book explores the fundamental scientific theories and technical principles behind the elements of laser additive manufacturing, touching upon scientific and technological challenges faced by laser additive manufacturing technology. This book is suitable for those who want to further "understand" and "master" laser additive manufacturing technology and will expose readers to innovative industrial applications that meet significant demand from aeronautical and astronautical high-end modern industries for low-cost, short-cycle and net-shape manufacturing of structure-function integrated metallic components. With the increasing use of industrial applications, additive manufacturing processes are deepening, with technology continuing to evolve. As new scientific and technological challenges emerge, there is a need for an interdisciplinary and comprehensive discussion of material preparation and forming, structure design and optimization, laser process and its control, microstructure and performance characterization, and innovative industrial applications, hence this book covers these important aspects.

Nanotechnology Tools for Infections Control: Scanning New Horizons on Next-Generation Therapies to Eradicate Pathogens and Fight Drug Resistance provides an overview of recent strategies to build nanotechnology platforms, with a specific focus on biocompatible and biodegradable nanosystems. Particular attention is given to responsive nanoparticles, which are able to sense and respond to specific external stimuli (e.g., temperature, pH). The book includes details of the rationale behind the design of the raw materials, synthetic procedures and characterization techniques. It also introduces a new generation of nanomaterials, commonly named as ‘nanobots’, which are able to self-propel in response to external stimuli. Subsequent sections of the book focus on the applications of nanosystems as an alternative approach to standard antibiotics. The chapters describe their pharmokinetic and dynamics within the body, their ability to cross biological barriers and how they distribute within different body compartments. In this respect, a dedicated section highlights the crucial role of the immune system, as well as of protein corona, in changing the nanoparticles retention within the body. Coverage is also given to describe how nanosystems access different cells and their intracellular trafficking.

Design and Manufacture of Structural Composites provides an overview of the main manufacturing challenges encountered when processing fibre-reinforced composite materials. Composites are unique in that the material is created at the same time as the structure, forming a very close link between the constituents, the manufacturing process and the resulting mechanical performance. This book takes an in-depth look at material choices and the intermediate steps required to convert different fibre and matrix combinations into finished products. It provides an insight into recent developments for each of the manufacturing processes covered, addressing design, cost, rate and mechanical performance. Topics covered include an introduction to composite materials, material preforming and conversion, moulding, digital design and sustainability, which addresses waste reduction, disassembly and fibre recovery. This book has been developed primarily as a teaching resource with contributions from leading experts in the field. The content has evolved from courses given by the authors to mechanical engineering and materials science students, at both undergraduate and postgraduate levels. It also draws upon experience gained during research projects and from leading industry experts. It therefore provides non-specialists with a valuable introduction to composite manufacturing techniques, helping to determine the most suitable manufacturing routes and to understand the challenges associated with the production of high-performance composite components.

The Resource Utilization of Plastic Waste with Supercritical Water Treatment discusses the types of plastic analysis, material characterization, technical principles of supercritical water treatment of waste plastics, the structure and process of the experimental platform, the selection of process parameters, and the establishment of kinetic models in professional areas of the field.