A discussion of the adsorption of inorganics from aqueous solution on inorganic adsorbents. It emphasizes the relationship between adsorption and surface charging, highlighting simple and complex adsorption systems sorted by the adsorbent as well as the adsorbate. The author includes a comprehensive collection of pristine PZC of different materials - covering crystallographic structure, methods of preparation, impurities in the solid, temperature and ionic composition of the solution, experimental methods to determine PZC, and the correlation between zero points and other physical quantities.
Scientific reference covers all surface coatings, paint types, components and formulationsSolvent-, water-based, polymeric, metallic, anti-corrosion, powder and advanced active coatingsChemical equations, molecular configurations and polymer chains linked to key structure/property relationsTechnical details on specialized coatings for marine, automotive and aerospace This professional reference is a unified account of the chemistry and materials science of virtually all major resins, paints, polymeric and inorganic coatings. It offers uniform analyses of the chemical formulations and molecular structures of widely used solvent- and water-based paints and coatings, including discussions of binders, pigments and fillers. In the context of a scientific analysis of structure-property relations the book addresses adhesion, shelf-life, durability, volatility, hardness, mechanical, optical and other engineered qualities. Emerging active coatings such as conductive, self-cleaning, self-healing paints/coatings, plus eco-friendly powder coatings, are included.
This book contains selected contributions on surface modification to improve the properties of solid materials. The surface properties are tailored either by functionalization, etching, or deposition of a thin coating. Functionalization is achieved by a brief treatment with non-equilibrium gaseous plasma containing suitable radicals that interact chemically with the material surface and thus enable the formation of rather stable functional groups. Etching is performed in order to modify the surface morphology. The etching parameters are selected in such a way that a rich morphology of the surfaces is achieved spontaneously on the sub-micrometer scale, without using masks. The combination of adequate surface morphology and functionalization of materials leads to superior surface properties which are particularly beneficial for the desired response upon incubation with biological matter. Alternatively, the materials are coated with a suitable thin film that is useful in various applications from food to aerospace industries.
A comprehensive and systematic treatment that focuses on surfaces and interfaces phenomena inhabited in biomimetic superhydrophobic materials, offering new fundamentals and novel insights. As such, this new book covers the natural surfaces, fundamentals, fabrication methods and exciting applications of superhydrophobic materials, with particular attention paid to the smart surfaces that can show switchable and reversible water wettability under external stimuli, such as pH, temperature, light, solvents, and electric fields. It also includes recent theoretical advances of superhydrophobic surfaces with regard to the wetting process, and some promising breakthroughs to promote this theory. As a result, materials scientists, physicists, physical chemists, chemical engineers, and biochemists will benefit greatly from a deeper understanding of this topic.
This book provides a multifaceted examination of solid waste management methods, the preparation, properties, and application of solid waste materials in the remediation of various environmental media, as well as the combination of solid waste materials and artificial intelligence. Based on the latest research results and cutting-edge technologies from around the world, the contributors combine the design principles of solid waste materials with application examples, including a complete system, clear routes, and illustrations. They integrate the idea of ecological civilization, the concept of sustainable development, and engineering innovation thinking, providing a reliable reference for resource recycling and contributing to global low-carbon emission. The book is suitable for teachers and students, as well as researchers, industrial technicians, and managers involved in solid waste resources and environmental remediation.
Principles of Regenerative Medicine, Third Edition, details the technologies and advances applied in recent years to strategies for healing and generating tissue. Contributions from a stellar cast of researchers cover the biological and molecular basis of regenerative medicine, highlighting stem cells, wound healing and cell and tissue development. Advances in cell and tissue therapy, including replacement of tissues and organs damaged by disease and previously untreatable conditions, such as diabetes, heart disease, liver disease and renal failure are also incorporated to provide a view to the future and framework for additional studies. - Comprehensively covers the interdisciplinary field of regenerative medicine with contributions from leaders in tissue engineering, cell and developmental biology, biomaterials sciences, nanotechnology, physics, chemistry, bioengineering and surgery - Includes new chapters devoted to iPS cells and other alternative sources for generating stem cells as written by the scientists who made the breakthroughs - Edited by a world-renowned team to present a complete story of the development and promise of regenerative medicine
Success or failure of biomaterials, whether tissue engineered constructs, joint and dental implants, vascular grafts, or heart valves, depends on molecular-level events that determine subsequent responses of cells and tissues. This book presents the latest developments and state-of-the-art knowledge regarding protein, cell, and tissue interactions with both conventional and nanophase materials. Insight into these biomaterial surface interactions will play a critical role in further developments in fields such as tissue engineering, regenerative medicine, and biocompatibility of implanted materials and devices. With chapters written by leaders in their respective fields, this compendium will be the authoritative source of information for scientists, engineers, and medical researchers seeking not only to understand but also to control tissue-biomaterial interactions.
The current status of the science and technology related to coatings, thin films and surface modifications produced by directed energy techniques is assessed in Materials Surface Processing by Directed Energy Techniques. The subject matter is divided into 20 chapters - each presented at a tutorial level – rich with fundamental science and experimental results. New trends and new results are also evoked to give an overview of future developments and applications. - Provides a broad overview on modern coating and thin film deposition techniques, and their applications - Presents and discusses various problems of physics and chemistry involved in the production, characterization and applications of coatings and thin films - Each chapter includes experimental results illustrating various models, mechanisms or theories
An Essential Guide to Electronic Material Surfaces and Interfaces is a streamlined yet comprehensive introduction that covers the basic physical properties of electronic materials, the experimental techniques used to measure them, and the theoretical methods used to understand, predict, and design them. Starting with the fundamental electronic properties of semiconductors and electrical measurements of semiconductor interfaces, this text introduces students to the importance of characterizing and controlling macroscopic electrical properties by atomic-scale techniques. The chapters that follow present the full range of surface and interface techniques now being used to characterize electronic, optical, chemical, and structural properties of electronic materials, including semiconductors, insulators, nanostructures, and organics. The essential physics and chemistry underlying each technique is described in sufficient depth for students to master the fundamental principles, with numerous examples to illustrate the strengths and limitations for specific applications. As well as references to the most authoritative sources for broader discussions, the text includes internet links to additional examples, mathematical derivations, tables, and literature references for the advanced student, as well as professionals in these fields. This textbook fills a gap in the existing literature for an entry-level course that provides the physical properties, experimental techniques, and theoretical methods essential for students and professionals to understand and participate in solid-state electronics, physics, and materials science research. An Essential Guide to Electronic Material Surfaces and Interfaces is an introductory-to-intermediate level textbook suitable for students of physics, electrical engineering, materials science, and other disciplines. It is essential reading for any student or professional engaged in surface and interface research, semiconductor processing, or electronic device design.
