Microstructural design of advanced engineering materials. (2013)
- Record Type:
- Book
- Title:
- Microstructural design of advanced engineering materials. (2013)
- Main Title:
- Microstructural design of advanced engineering materials
- Further Information:
- Note: Edited by Dmitri A. Molodov.
- Editors:
- Molodov, Dmitri A, 1954-
- Contents:
- PREFACE; ; PART I: Materials Modeling and Simulation: Crystal Plasticity, Deformation, and Recrystallization; ; THROUGH-PROCESS MODELING OF MATERIALS FABRICATION: PHILOSOPHY, CURRENT STATE, AND FUTURE DIRECTIONS; Introduction; Microstructure Evolution; Microstructural Processes; Through-Process Modeling; Future Directions; ; APPLICATION OF THE GENERALIZED SCHMID LAW IN MULTISCALE MODELS: OPPORTUNITIES AND LIMITATIONS; Introduction; Crystal Plasticity; Polycrystal Plasticity Models for Single-Phase Materials; Plastic Anisotropy of Polycrystalline Materials; Experimental Validation; Conclusions; ; CRYSTAL PLASTICITY MODELING; Introduction; Fundamentals; Application Examples; Conclusions and Outlook; ; MODELING OF SEVERE PLASTIC DEFORMATION: TIME-PROVEN RECIPES AND NEW RESULTS; Introduction; One-Internal Variable Models; Two-Internal Variable Models; Three-Internal Variable Models; Numerical Simulations of SPD Processes; Concluding Remarks; ; PLASTIC ANISOTROPY IN MAGNESIUM ALLOYS - PHENOMENA AND MODELING; Deformation Modes and Textures; Anisotropy of Stress and Strain; Modeling Anisotropic Stress and Strain; Concluding Remarks; ; APPLICATION OF STOCHASTIC GEOMETRY TO NUCLEATION AND GROWTH TRANSFORMATIONS; Introduction; Mathematical Background and Basic Notation; Revisiting JMAK; Nucleation in Clusters; Nucleation on Lower Dimensional Surfaces; Analytical Expressions for Transformations Nucleated on Random Planes; Random Velocity; Simultaneous and Sequential Transformations;PREFACE; ; PART I: Materials Modeling and Simulation: Crystal Plasticity, Deformation, and Recrystallization; ; THROUGH-PROCESS MODELING OF MATERIALS FABRICATION: PHILOSOPHY, CURRENT STATE, AND FUTURE DIRECTIONS; Introduction; Microstructure Evolution; Microstructural Processes; Through-Process Modeling; Future Directions; ; APPLICATION OF THE GENERALIZED SCHMID LAW IN MULTISCALE MODELS: OPPORTUNITIES AND LIMITATIONS; Introduction; Crystal Plasticity; Polycrystal Plasticity Models for Single-Phase Materials; Plastic Anisotropy of Polycrystalline Materials; Experimental Validation; Conclusions; ; CRYSTAL PLASTICITY MODELING; Introduction; Fundamentals; Application Examples; Conclusions and Outlook; ; MODELING OF SEVERE PLASTIC DEFORMATION: TIME-PROVEN RECIPES AND NEW RESULTS; Introduction; One-Internal Variable Models; Two-Internal Variable Models; Three-Internal Variable Models; Numerical Simulations of SPD Processes; Concluding Remarks; ; PLASTIC ANISOTROPY IN MAGNESIUM ALLOYS - PHENOMENA AND MODELING; Deformation Modes and Textures; Anisotropy of Stress and Strain; Modeling Anisotropic Stress and Strain; Concluding Remarks; ; APPLICATION OF STOCHASTIC GEOMETRY TO NUCLEATION AND GROWTH TRANSFORMATIONS; Introduction; Mathematical Background and Basic Notation; Revisiting JMAK; Nucleation in Clusters; Nucleation on Lower Dimensional Surfaces; Analytical Expressions for Transformations Nucleated on Random Planes; Random Velocity; Simultaneous and Sequential Transformations; Final Remarks; ; IMPLEMENTATION OF ANISOTROPIC GRAIN BOUNDARY PROPERTIES IN MESOSCOPIC SIMULATIONS; Introduction; Overview of Simulation Methods; Anisotropy of Grain Boundaries; Simulation Approaches; Summary; ; PART II: Interfacial Phenomena and their Role in Microstructure Control; ; GRAIN BOUNDARY JUNCTIONS: THEIR EFFECT ON INTERFACIAL PHENOMENA; Introduction; Experimental Measurement of Grain Boundary Triple Line Energy; Impact of Triple Line Tension on the Thermodynamics and Kinetics in Solids; Why do Crystalline Nanoparticles Agglomerate with Low Misorientations?; Concluding Remarks; ; PLASTIC DEFORMATION BY GRAIN BOUNDARY MOTION: EXPERIMENTS AND SIMULATIONS; Introduction; What is the Coupled Grain Boundary Motion?; Computer Simulation Methodology; Experimental Methodology; Multiplicity of Coupling Factors; Dynamics of Coupled GB Motion; Coupled Motion of Asymmetrical Grain Boundaries; Coupled Grain Boundary Motion and Grain Rotation; Concluding Remarks; ; GRAIN BOUNDARY MIGRATION INDUCED BY A MAGNETIC FIELD: FUNDAMENTALS AND IMPLICATIONS FOR MICROSTRUCTURE EVOLUTION; Introduction; Driving Forces for Grain Boundary Migration; Magnetically Driven Grain Boundary Motion in Bicrystals; Selective Grain Growth in Locally Deformed Zn Single Crystals under a Magnetic Driving Force; Impact of a Magnetic Driving Force on Texture and Grain Structure Development in Magnetically Anisotropic Polycrystals; Magnetic Field Influence on Texture and Microstructure Evolution in Polycrystals Due to Enhanced Grain Boundary Motion; ; INTERFACE SEGREGATION IN ADVANCED STEELS STUDIED AT THE ATOMIC SCALE; Motivation for Analyzing Grain and Phase Boundaries in High-Strength Steels; Theory of Equilibrium Grain Boundary Segregation; Atom Probe Tomography and Correlated Electron Microscopy on Interfaces in Steels; Atomic-Scale Experimental Observation of Grain Boundary Segregation in the Ferrite Phase of Pearlitic Steel; Phase Transformation and Nucleation on Chemically Decorated Grain Boundaries; Conclusions and Outlook; ; INTERFACE STRUCTURE-DEPENDENT GRAIN GROWTH BEHAVIOR IN POLYCRYSTALS; Introduction; Fundamentals: Equilibrium Shape of the Interface; Grain Growth in Solid -; Liquid Two-Phase Systems; Grain Growth in Solid-State Single-Phase Systems; Concluding Remarks; ; CAPILLARY-MEDIATED INTERFACE ENERGY FIELDS: DETERMINISTIC DENDRITIC BRANCHING; Introduction; Capillary Energy Fields; Capillarity-Mediated Branching; Branching; Dynamic Solver Results; Conclusions; ; PART III: Advanced Experimental Approaches for Microstructure Characterization; ; HIGH ANGULAR RESOLUTION EBSD AND ITS MATERIALS APPLICATIONS; Introduction: Some History of HR-EBSD; HR-EBSD Methods; Applications; Discussion; Conclusions; ; 4D CHARACTERIZATION OF METAL MICROSTRUCTURES; Introduction; 4D Characterizations by 3DXRD - From Idea to Implementation; Examples of Applications; Challenges and Suggestions for the Future Success of 3D Materials Science; Concluding Remarks; ; CRYSTALLOGRAPHIC TEXTURES AND A MAGNIFYING GLASS TO INVESTIGATE MATERIALS; Introduction; Texture Evolution and Exploitation of Related Information in Metal Processing; Summary; ; Part IV: Applications: Grain Boundary Engineering and Microstructural Design for Advanced Properties; ; THE ADVENT AND RECENT PROGRESS OF GRAIN BOUNDARY ENGINEERING (GBE): IN FOCUS ON GBE FOR FRACTURE CONTROL THROUGH TEXTURING; Introduction; Historical Background; Basic Concept of Grain Boundary Engineering; Characteristic Features of Grain Boundary Microstructures; Relation between Texture and Grain Boundary Microstructure; Grain Boundary Engineering for Fracture Control through Texturing; Conclusion; ; MICROSTRUCTURE AND TEXTURE DESIGN OF NIAL VIA THERMOMECHANICAL PROCESSING; Introduction; Experimental; Microstructure and Texture Development; Texture Simulations; Mechanical Anisotropy; Conclusions; ; DEVELOPMENT OF NOVEL METALLIC HIGH TEMPERATURE MATERIALS BY MICROSTRUCTURAL DESIGN; Introduction; Alloy System Mo-Si-B; Alloy System Co-Re-Cr; Conclusions; ; INDEX; ; … (more)
- Publisher Details:
- Place of publication not identified : Wiley-VCH
- Publication Date:
- 2013
- Extent:
- 1 online resource (530 pages)
- Subjects:
- 620.11299
Microstructure - Languages:
- English
- ISBNs:
- 9783527652839
- Access Rights:
- Legal Deposit; Only available on premises controlled by the deposit library and to one user at any one time; The Legal Deposit Libraries (Non-Print Works) Regulations (UK).
- Access Usage:
- Restricted: Printing from this resource is governed by The Legal Deposit Libraries (Non-Print Works) Regulations (UK) and UK copyright law currently in force.
- View Content:
- Available online (eLD content is only available in our Reading Rooms) ↗
- Physical Locations:
- British Library HMNTS - ELD.DS.505990
- Ingest File:
- 03_080.xml