Heterostructured Metals: Processing, Interfaces, Defect Structures and Deformation Mechanisms presents an in-depth exploration of the intricate defect structures and deformation mechanisms found in nano and heterostructured metallic systems, with a particular focus on interphase boundaries. The book introduces readers to the atomic-level details, thermodynamics, and kinetics governing defect-interface interactions, and explains how these factors influence the mechanical behavior of metals. Through a combination of examples and forward-looking perspectives, it highlights the importance of these…mehr
Heterostructured Metals: Processing, Interfaces, Defect Structures and Deformation Mechanisms presents an in-depth exploration of the intricate defect structures and deformation mechanisms found in nano and heterostructured metallic systems, with a particular focus on interphase boundaries. The book introduces readers to the atomic-level details, thermodynamics, and kinetics governing defect-interface interactions, and explains how these factors influence the mechanical behavior of metals. Through a combination of examples and forward-looking perspectives, it highlights the importance of these topics for future research and technological advancements in materials science. In addition to foundational concepts, this volume features a variety of model and engineering alloy systems, including both cubic and non-cubic crystals. It showcases state-of-the-art computational techniques at the atomistic and meso-scale levels, and describes advanced experimental approaches such as nanomechanical testing and in situ characterization. The book also outlines material synthesis methods using physical vapor deposition, as well as melt and deformation processing, providing a comprehensive resource for researchers and engineers in the field.
Amit Misra is the Edward DeMille Campbell Collegiate Professor of Materials Science & Engineering (MSE) at the University of Michigan (UM), Ann Arbor. He served as MSE Department Chair at UM from 2014-2022. Prior to joining UM in 2014, he worked for nearly 18 years at Los Alamos National Laboratory (LANL). He received is PhD (MSE) degree from University of Michigan in 1994 and Bachler's (Metallurgical Engineering from IT-BHU (now IIT-Varanasi), India. His research expertise includes metallic materials processing by physical vapor deposition, laser additive manufacturing and deformation processing, small-scale mechanical testing and characterization using scanning and transmission electron microscopy including in situ nanomechanics. He is a Fellow of TMS, MRS, ASM-International, AAAS and LANL, and was recognized with TMS Cyril Stanley Smith Award, TMS Brimacombe Medalist, TMS-MPMD Distinguished Scientist/Engineer Award; and TMS-MPMD Distinguished Service Award.
Inhaltsangabe
1. Introduction: High-strength Metallic Materials 2. Computational Methods 3. Atomic Structures, Point Defect Thermodynamics and Kinetics and Interfacial Mechanical Properties 4. Glide Dislocation-Interphase Boundary Interactions 5. Experimental Methods 6. Deformation Mechanisms Maps in Nanolaminates 7. Deformation Mechanisms in Hetero-structured Composites 8. Meso-scale modeling of stress-strain response of nanolaminates 9. Interface Stability under Extreme Conditions 10. Outlook
