Chemists working to improve paints and coatings require quick and reliable ways to gauge how the new products will age. The field has seen significant recent progress and this volume collects many of the new methods. It includes methods for characterizing outdoor and lab test chambers, related statistical methods, research on the chemistry and mechanics of failure, and current work on large data bases of experimental results. The book describes how to measure the environmental factors and the changes which occur in coatings, and then how to relate this information to cumulative damage models. It also discusses methods for risk management.
The collection of twenty-seven papers published has been grouped into six major categories : corrosion process characterization and modeling, applications of Kramers-Kronig transformations for evaluating the validity of data, corrosion and its inhibition by either corrosion products of specially added inhibitors, corrosion of aluminum and aluminum alloys, corrosion of steel in soils and concrete, and evaluation of coatings on metal substrates.
The field of coatings and thin-film technologies is rapidly advancing to keep up with new uses for semiconductor, optical, tribological, thermoelectric, solar, security, and smart sensing applications, among others. In this sense, thin-film coatings and structures are increasingly sophisticated with more specific properties, new geometries, large areas, the use of heterogeneous materials and flexible and rigid coating substrates to produce thin-film structures with improved performance and properties in response to new challenges that the industry presents. This book aims to provide the reader with a complete overview of the current state of applications and developments in thin-film technology, discussing applications, health and safety in thin films, and presenting reviews and experimental results of recognized experts in the area of coatings and thin-film technologies.
Service Life Prediction of Polymers and Coatings: Enhanced Methods focuses on the cutting-edge science behind how plastic and polymer materials are modified by the effects of weathering, offering the latest advances in service life prediction methods. The chapters have been developed by experts based on their contributions as part of the 7th Service Life Prediction Meeting. The volume begins with the premise that it is possible to produce and design life predictions, also looking at how these predictions can be used. Subsequent chapters present new developments in service life prediction, examining the most important considerations in SLP design, timescales, and other major issues. The book also considers the current state of the field in terms of both accomplishments and areas that require significant research going forward. This is a highly valuable reference for engineers, designers, technicians, scientists and R&D professionals who are looking to develop materials, components or products for outdoor applications across a range of industries. The book also supports academic researchers, scientists and advanced students with an interest in service life, the effects of weathering, material degradation, failure analysis, or sustainability across the fields of plastics engineering, polymer science and materials science. - Presents novel prediction techniques for plastics and polymers exposed to outdoor weathering - Provides a consensus roadmap on the scientific barriers related to a validated, predictive model for the response of polymer and plastics to outdoor exposure - Enables the reader to assess and compare different methods and approaches to service life prediction
This book provides an accessible way to learn about organic coatings and finishing. The coating materials are considered here from the angle of chemical reactions and mechanisms of film formation. The examples and exercises provided in here will also help the reader achieve technical insights into the subject and obtain a deep understanding of the principles underlying the technology. This book also provides the reader with the basic knowledge and skills required for handling mixtures. As rheological technology has been widely used in research papers for academic exchange and solving technical problems on organic coatings and finishing, this book collects and compiles a number of reference works on rheological technology, demonstrating how to use it in organic coatings and finishing.
Some of the futuristic applications are nanotubes for electrically conductive coatings and to increase the rate of reaction of thermoset resins; organosilane dendrimer coatings; buckyball coatings for machine parts; and metals for conductive coatings in inks. The technology is limited to substantially specialized applications due to the high cost per unit volume needed to reduce the size of the particles and the need to add surface modifiers to prevent the particles from agglomerating. Recent research efforts focus primarily on the functionalization of the particle surface of the nanoparticles to make them more compatible with the coating resin systems, so that easy dispersion, low viscosity, and covalent bonding are provided between the particles and the resins.
This book discusses new experimental methods and instrumental techniques that can provide a numerical assessment of the corrosion resistant properties of organic coatings. It explores new materials for corrosion protection, including conductive polymers. It also looks at the performance of organic coatings under various environmental conditions and investigates organic coatings for aluminum alloys.
