Bulk nanostructured materials with multifunctional properties

This book presents a multifunctional approach to the design of bulk nanostructured metals through severe plastic deformation (SPD). Materials engineering has traditionally involved selecting a suitable material for a given application. However, modern engineering frequently requires materials with a set of multifunctional, often conflicting properties: Enhanced mechanical properties need to be combined with improved physical (electrical, magnetic, etc.) and/or chemical (corrosion resistance, biocompatibility) properties. So disparate materials properties need to be engineered and optimized simultaneously. These requirements have created a paradigm shift in which the classical materials selection approach is replaced by design of material microstructures to achieve certain performance requirements, subject to constraints on individual properties such as strength, conductivity, and corrosion resistance. Written by researchers at the forefront of this new materials design approach, the present volume provides a comprehensive introduction to multifunctional design of bulk nanostructured materials, with applications ranging from hydrogen storage to construction engineering.

Introduction.- Nanostructural design of materials for advanced properties.- Grain refinement via severe plastic deformation.- Precipitation of second phases in alloys during and/or after severe plastic deformation.- Grain boundary engineering via severe plastic deformation.- Dislocation structure of metallic materials after severe plastic deformation.- Nanotwins and stacking faults in metallic materials after severe plastic deformation.- Multifunctional properties of bulk nanostructured metallic materials.- Superstrength and enhanced mechanical properties.- Superstrength and ductility.- Fatigue properties.- Wear resistance.- Improved physical and functional properties.- Thermo-electrical conductivity.- Magnetic properties.- Irradiation resistance.- Enhanced chemical properties.- Corrosion resistance.- Biocompatibility.- Applications Areas.- Ti-based materials in bio-medical engineering.- Nanostructured Al alloys and Cu in electrical engineering and micro-electro-mechanical systems.- Bulk nanometals for hydrogen storage.- Magnets from bulk nanomaterials.- Bulk nanomaterials in the sports industry.- Bulk nanomaterials in construction engineering.