This book is devoted to the rapidly developing field of oxide thin-films and heterostructures. Oxide materials combined with atomic-scale precision in a heterostructure exhibit an abundance of macroscopic physical properties involving the strong coupling between the electronic, spin, and structural degrees of freedom, and the interplay between magnetism, ferroelectricity, and conductivity. Recent advances in thin-film deposition and characterization techniques made possible the experimental realization of such oxide heterostructures, promising novel functionalities and device concepts. The book consists of chapters on some of the key innovations in the field over recent years, including strongly correlated oxide heterostructures, magnetoelectric coupling and multiferroic materials, thermoelectric phenomena, and two-dimensional electron gases at oxide interfaces. The book covers the core principles, describes experimental approaches to fabricate and characterize oxide heterostructures, demonstrates new functional properties of these materials, and provides an overview of novel applications.

This volume collects numerous recent advances in the study of stratified fluids. It includes analytical and experimental work from a wide range of fields, including meteorology, limnology, oceanography, and the study of estuarine processes. It also includes fundamental research on stratified and rotating fluid dynamics. A compendium of current work, the book is an ideal starting point for future research.

Approx.400 pages

Transport phenomena are the processes and rules by which heat, mass, and momentum move through and between materials and systems. Along with thermodynamics, mechanics, and electromagnetism, this body of knowledge and theory forms the core principals of all physical systems and is essential to all engineering disciplines. This new edition of a classic work on how transport phenomena behave in materials and materials systems will provide expanded coverage and up-to-date theory and knowledge from today's research on heat transfer and fluid behavior, with ample examples of practical applications to materials processing and engineering. Professional engineers and students alike will find one of the clearest and most accessible approaches to an often difficult and challenging subject. Logical pedagogy, with clear applications to real materials engineering problems will make more vivid the abstract body of knowledge that comprises today's understanding of transport phenomena. Readers will find: A new chapter on boiling and condensationRevised chapters on heat transport, mass transport in solid state and mass transport in fluidsRevised and expanded end-of-chapter problems and exercisesS.I. Units throughoutExtensive Appendices of standard materials propertiesFor classroom use, a Solutions Manual is available

More than four decades have passed since surface-enhanced Raman scattering (SERS) was discovered. In today's world SERS has been established as a plasmon-based spectroscopy with ultra-high sensitivity and versatility at the forefront of the developments in plasmonics. SERS has been developing with the advances in nanoscience and nanotechnology. The "SERS world" has grown up markedly for the last 20 years or so, and recently the wider concept of, plasmon-enhanced spectroscopy was born. Plasmon-enhanced spectroscopy contains not only SERS but also tip-enhanced Raman scattering (TERS), surface-enhanced infrared absorption (SEIRA), surface-enhanced fluorescence (SEF), and more. Through these novel spectroscopies various amazing properties of plasmons have become known, providing new exciting research fields. One of the main purposes of the book is to convey the enthusiastic discussion on plasmon-enhanced spectroscopy at the symposium to the scientific community. This book reports leading-edge advances in the theory of plasmonic enhancement and application of plasmon-enhanced spectroscopy to biology, chemistry, physics, materials science, and medicine. Many books have been published about SERS, but this may be the first time that a book on a wide area of plasmon-enhanced spectroscopy has ever been published. The book consists of two volumes; the second volume discusses TERS, SEIRA, and other topics related to plasmon-enhanced spectroscopy.

The climate change crisis presents a multi-dimensional challenge to the development of the built environment. With finite global resources and increasingly unpredictable climate patterns, the need to improve our understanding of sustainable practices and materials for construction has never been more pressing. The Handbook of Research on Corrosion Sciences and Engineering aims to shed light on the recent developments in the usage of sustainable materials to protect metallic materials against corrosion and provides emerging research exploring the theoretical and practical aspects of corrosion engineering science and technology. Covering key topics such as machine learning, smart coating, sustainability, and artificial intelligence, this major reference work is ideal for construction workers, industry professionals, researchers, academicians, scholars, practitioners, instructors, and students.

Approx.450 pages

Bioengineered Nanomaterials for Wound Healing and Infection Control is a key reference for those working in the fields of materials science, pharmacy, nanotechnology, biomedical engineering and microbiology. Bioengineered nanomaterials have unique physicochemical properties which promote accelerated wound healing and treatment of infections. The biosynthesis of these nanomaterials also offers a clean, safe and renewable alternative to traditional nanomaterials, helping reduce environmental impact alongside antibacterial resistance.

Ceramic Matrix Composites: Lifetime and Strength Prediction Under Static and Stochastic Loading focuses on the strain response and lifetime prediction of fiber-reinforced ceramic-matrix composites under stress-rupture loading at intermediate temperatures. Typical damage mechanisms of matrix cracking, interface debonding and oxidation, and fiber's oxidation and fracture are considered in the micromechanical analysis. Effects of composite's constituent properties, peak stress, and testing temperature on the composite's strain response and lifetime are analyzed in detail. Comparison of constant and different stochastic stress spectrum on composite's damage evolution and fracture are also discussed. The book will be a practical guide for the material researcher and component designer needing to better understand the composite's damage and fracture behavior under stress-rupture loading at intermediate temperatures.

Functionalized Nanomaterials for Biosensing and Bioelectronics Applications: Trends and Challenges describes current and future opportunities for integrating the unique properties of two-dimensional nanomaterials with bioelectronic interfaces. Sections focus on background information and fundamental concepts, review the available functionalized nanomaterials and their properties, explore the integration of functionalized nanomaterials with bioelectronics, including available fabrication and characterization methods, electrical behavior at the interface, and design and synthesis guidelines, and review examples of microsystems where functionalized nanomaterials are being integrated with bioelectronics. This book is suitable for researchers and practitioners in academia and R&D working in materials science and engineering, analytical chemistry and related fields.

Plasmonic Materials and Metastructures: Fundamentals, Current Status, and Perspectives reviews the current status and emerging trends in the development of conventional and alternative plasmonic materials. Sections cover fundamentals and emerging trends of plasmonic materials development, including synthesis strategies (chemical and physical) and optical characterization techniques. Next, the book addresses fundamentals, properties, remaining barriers for commercial translation, and the latest advances and opportunities for conventional noble metal plasmonic materials. Fundamentals and advances for alternative plasmonic materials are also reviewed, including two-dimensional hybrid materials composed of graphene, monolayer transition metal dichalcogenides, boron nitride, etc. In addition, other sections cover applications of plasmonic metastructures enabled by plasmonic materials with improved material properties and newly discovered functionalities. Applications reviewed include quantum plasmonics, topological plasmonics, chiral plasmonics, nanolasers, imaging (metalens), active, and integrated technologies.

More than four decades have passed since surface-enhanced Raman scattering (SERS) was discovered. In today's world SERS has been established as a plasmon-based spectroscopy with ultra-high sensitivity and versatility at the forefront of the developments in plasmonics. SERS has been developing with the advances in nanoscience and nanotechnology. The "SERS world" has grown up markedly for the last 20 years or so, and recently the wider concept of, plasmon-enhanced spectroscopy was born. Plasmon-enhanced spectroscopy contains not only SERS but also tip-enhanced Raman scattering (TERS), surface-enhanced infrared absorption (SEIRA), surface-enhanced fluorescence (SEF), and more. Through these novel spectroscopies various amazing properties of plasmons have become known, providing new exciting research fields. One of the main purposes of the book is to convey the enthusiastic discussion on plasmon-enhanced spectroscopy at the symposium to the scientific community. This book reports leading-edge advances in the theory of plasmonic enhancement and application of plasmon-enhanced spectroscopy to biology, chemistry, physics, materials science, and medicine. Many books have been published about SERS, but this may be the first time that a book on a wide area of plasmon-enhanced spectroscopy has ever been published. The book consists of two volumes; the first volume contains the introductory review by George Schatz followed by eight chapters, which are mainly concerned with SERS.

Nanoscale Memristor Device and Circuits Design provides theoretical frameworks, including (i) the background of memristors, (ii) physics of memristor and their modeling, (iii) menristive device applications, and (iv) circuit design for security and authentication. The book focuses on a broad aspect of realization of these applications as low cost and reliable devices. This is an important reference that will help materials scientists and engineers understand the production and applications of nanoscale memrister devices. A memristor is a two-terminal memory nanoscale device that stores information in terms of high/low resistance. It can retain information even when the power source is removed, i.e., "non-volatile." In contrast to MOS Transistors (MOST), which are the building blocks of all modern mobile and computing devices, memristors are relatively immune to radiation, as well as parasitic effects, such as capacitance, and can be much more reliable. This is extremely attractive for critical safety applications, such as nuclear and aerospace, where radiation can cause failure in MOST-based systems.

Polyurea: Synthesis, Properties, Composites, Production, and Applications is a comprehensive and practical guide to polyurea, a material used for its exceptional properties and performance in a range of high value industrial applications. Sections cover polyurea formulations and properties, comparing aromatic polyurea with aliphatic polyurea and computation modeling of properties for polyurea and polyurea composites. This is followed by in-depth coverage of synthesis, structure and production methods of polyurea, with the connections between production, performance and properties examined thoroughly. Other sections explain the preparation, characterization, modeling and applications of polyurea and polyurea composites with the required properties for specific advanced applications. Finally, environmental issues, recycling and future potential of polyurea are considered. This is a valuable resource for researchers and advanced students in polymer science, chemistry, composite science, civil engineering, materials science and mechanical engineering, as well as R&D professionals, engineers and industrial scientists with an interest in polyurea-based materials for advanced applications.

Mining and Processing Residues: Future’s Source of Critical Raw Materials provides a comprehensive review of principal aspects of CRM-containing residues re-processing, including available sampling and analytical techniques, the latest available processing technologies, authorization and legal matters, and analysis of environmental, social, and economic impacts. Suitable for academic researchers, practicing engineers and students, the book is aimed at giving a complete and multilateral view of CRM recovery from the residues.

Principles of Biomaterials Encapsulation: Volume Two provides an expansive and in-depth resource covering the key principles, biomaterials, techniques and applications of encapsulation in translational medicine. The book details the various biomaterials available for encapsulation, including polymers, natural and synthetic biomaterials, porous materials, and more. The advantages and disadvantages of conventional and contemporary biomaterials for encapsulations are reviewed, along with advice on the most effective materials for both shell and core. The final part of the book describes a broad range of applications in regenerative medicine, uniquely bringing encapsulation into the worlds of translational medicine and tissue engineering. This book enables readers to learn about the pros and cons of different biomaterials for encapsulation, as well as how they can be utilized in many bodily systems and tissues, such as the respiratory, digestive, endocrine and cardiovascular systems. Written and edited by well-versed materials scientists with extensive clinical, biomedical and regenerative medicine experience, this book offers a deeply interdisciplinary look at encapsulation in translational medicine.

Natural Materials-based Green Composites 1: Plant Fibers explores several important plant fiber-based materials such as wood fibers, vegetable fibers, jute fibers, stalk fibers and hemp fibers. The book provides introductory information and various innovative applications of most important plant fiber-based materials such as wood fibers, vegetable fibers, jute fibers, stalk fibers, and hemp fibers.It investigates their structure and provides various innovative applications and discusses the microstructure of wood and mechanical properties of green wood-based composites (GWC), eco-friendly applications of green composites as building materials, and applications in wastewater treatment. The book also discusses seaweed and cotton fibers for their applications as adhesive and in reinforcement.The book is complemented by Natural Materials-based Green Composites 2: Biomass that deals with a broad range of material types, including natural fiber reinforced polymer composites, particulate composites, fiberboard, wood fiber composites, and plywood composite that utilize natural, renewable, and biodegradable agricultural biomass.

Applications of Nanostructured Ferrites provides an overview of materials design and characterization of ferrite nanomaterials for a diverse array of applications. In particular, the book investigates the large-scale use of ferrite materials, an important category of magnetic materials for environmental remediation such as waste water treatment. In addition, it considers ferrites to enable new technologies in energy, sensing, flexible and conductive electronics, and MEMs applications. This book is suitable for researchers and practitioners in the disciplines of materials science, engineering, chemistry and physics.

Polysaccharide-Based Hydrogels: Synthesis, Characterization and Applications looks at the synthesis, characterization and application of polysaccharide-based materials in a broad array of fields. The book discusses the role of polysaccharides in the preparation of hydrogels, the use of hydrogel-based green materials, and their applications in biomedical applications, drug delivery, water purification techniques, food industries, agricultural fields, and pharmaceuticals applications. Written by leading experts in this field, this book will be a valuable reference for scientists, academicians, researchers, technologists, consultants and policymakers.

BSIM-Bulk Mosfet Model for Wireless and Mixed-Mode ICs provides in-depth knowledge of the internal operation of the model. The authors not only discuss the fundamental core of the model, but also provide details of the recent developments and new real-device effect models. In addition, the book covers the parameter extraction procedures, addressing geometrical scaling, temperatures, and more. There is also a dedicated chapter on extensive quality testing procedures and experimental results. This book discusses every aspect of the model in detail, and hence will be of significant use for the industry and academia. Those working in the semiconductor industry often run into a variety of problems like model non-convergence or non-physical simulation results. This is largely due to a limited understanding of the internal operations of the model as literature and technical manuals are insufficient. This also creates huge difficulty in developing their own IP models. Similarly, circuit designers and researcher across the globe need to know new features available to them so that the circuits can be more efficiently designed.

Nanostructured Materials for Tissue Engineering introduces the key properties and approaches involved in using nanostructured materials in tissue engineering, including functionalization, nanotechnology-based regenerative techniques, toxicological and biocompatible aspects. A broad range of nanomaterial types are covered, from polymer scaffolds and nanocomposites to gold nanoparticles and quantum dots. This book aids the reader in materials selection, as well as matching to the best applications, including bone, skin, pulmonary or neurological tissue engineering. Users will find this book to be an up-to-date review on this fast-changing field that is ideal for materials scientists, tissue engineers, biomedical engineers, and pharmaceutical scientists.

Biomaterials for Neural Tissue Engineering covers a range of materials and technologies used for regenerating or repairing neural tissue. With a strong focus on biomaterials and scaffolds, the book examines the testing and evaluation pathway for in-vitro and in-vivo testing trials. This book introduces the reader to the fundamentals of the nervous system from a tissue engineering perspective and goes on to describe contemporary technologies used in the development of neural repair materials, as well as currently available biomaterials suitable for neural tissue repair and regeneration. This detailed reference is ideal for those who are new to using biomaterials in tissue engineering, particularly those interested in the nervous system, including academics and early career researchers in the fields of materials science, regenerative medicine, biomedical engineering and clinical sciences.

Solar Energy Harvesting, Conversion and Storage: Materials, Technologies and Applications focuses on the current state of solar energy and the recent advancements in nanomaterials for different technologies, from harnessing energy to storage. The book covers different aspects of advanced nanomaterials for solar energy, rapid developments in solar thermal and hot water systems, and PV and CSP technologies. The book also discusses storing harnessed solar/heat energy using different available energy storage technologies, including phase change materials (PCMs), batteries, and supercapacitors. Various applications such as agriculture and aquaculture, desalination, domestic appliances, and transport are explored, as well.