Narita / Wang Piezoelectric Materials, Composites, and Devices

Piezoelectric Materials, Composites, and Devices: Fundamentals, Mechanics, and Applications offers practical guidance on piezoelectric materials and composites, as well as their applications on various devices. It starts with a clear overview of piezoelectric fundamentals, key parameters, and standard characterization techniques. The book also details the structure and properties of various piezoelectric materials, including single crystals, ceramics, polymers, 2-dimensional materials, and their composites. It combines numerical simulations with precise measurements for accurate characterization of these materials. The book simplifies complex concepts by presenting basic equations and models, aiding in the understanding of stress and electric fields within piezoelectric devices. The reliability and durability (fracture and fatigue) of piezoelectric materials and composites are also explained, and the final sections of the book explore the applications of piezoelectric materials on sensors, energy harvesters, and actuators, highlighting the capabilities of advanced piezoelectric materials. - Concisely explains the fundamentals of the mechanical and physical behavior of piezoelectric materials and composites using simple formulas and illustrations - Outlines numerical modeling and simulation techniques, providing a better understanding of piezoelectric materials - Discusses a wide range of high-performance and lightweight piezoelectric composites, methods of performance evaluation, device design, and life evaluation - Includes design guidelines for various sensors, energy harvesters and actuators

Fumio Narita is a Professor in the Department of Frontier Sciences for Advanced Environment, Graduate School of Environmental Studies, Tohoku University, Japan. His current research focuses on the design and development of piezoelectric/magnetostrictive materials and structures in energy harvesting and self-powered environmental monitoring. He is extensively using state-of-the-art electromagneto-mechanical characterization techniques in combination with computational multiscale modeling to understand the fundamental structure-property relations of complex multifunctional composite materials.