Most processed materials retain a memory of their production process at the molecular level. Subtle changes in production-such as variations in temperature or the presence of impurities-can impart performance benefits or drawbacks to individual batches of products. Some product developers have taken advantage of this process dependency to tailor properties to specific customer needs. In other cases, poorly engineered processes have resulted in serious failures. Process Techniques for Engineering High-Performance Materials explores practical strategies to guide you in systematically developing, improving, and producing engineered materials.The book describes an R&D approach that is common to many material types, from polymers, biochemicals, metal alloys, and composites to coatings, ceramics, elastomers, and processed foods. Throughout, hundreds of examples illustrate successes and disasters in the history of materials development. These examples clearly show how product management and development tactics are constrained by the nature of the production process and the strategy of the company.The author offers practical advice on how to:Foster creativity in an industrial environment and avoid factors that unintentionally suppress technical innovationDevelop products when the properties of the product are highly dependent on processing variablesAvoid the inevitable scale-up problems that occur on process-dependent materialsGet the most out of expensive trial work in a production plant environmentCombine products into a systems solution to customer problemsHighlighting important rules for product development, this book helps you better understand the mechanics of engineering processed materials and how to adjust your processes to improve performance.