Includes bibliographical references and index.

"With its proven concept, this textbook introduces topics relevant to the design of new materials. It covers a wide range of topics in the area of inorganic materials structure/property relations and materials behavior across length scales. New to this third edition are chapters specifically on computational materials science, compound semiconductors, intermetallic compounds, and covalent compounds. Also, there are expanded discussions on several topics, including microstructural considerations, transport properties, magnetic and dielectric properties, and nanomaterials. This textbook therefore provides a state-of-the-art introduction to inorganic materials design for advanced students of materials science, chemistry and engineering"-- Provided by publisher.

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Cover -- Title Page -- Copyright Page -- Contents -- Foreword to Second Edition -- Foreword to First Edition -- Preface to Third Edition -- Preface to Second Edition -- Preface to First Edition -- Acronyms -- Chapter 1 Crystallographic Considerations -- 1.1 Degrees of Crystallinity -- 1.1.1 Monocrystalline Solids -- 1.1.2 Quasicrystalline Solids -- 1.1.3 Polycrystalline Solids -- 1.1.4 Semicrystalline Solids -- 1.1.5 Amorphous Solids -- 1.2 Basic Crystallography -- 1.2.1 Crystal Geometry -- 1.3 Single-Crystal Morphology and Its Relationship to Lattice Symmetry

1.4 Twinned Crystals, Grain Boundaries, and Bicrystallography -- 1.4.1 Twinned Crystals and Twinning -- 1.4.2 Crystallographic Orientation Relationships in Bicrystals -- 1.5 Amorphous Solids and Glasses -- 1.5.1 Oxide Glasses -- 1.5.2 Metallic Glasses and Metal-Organic Framework Glasses -- 1.5.3 Aerogels -- Practice Problems -- References -- Chapter 2 Microstructural Considerations -- 2.1 Materials Length Scales -- 2.1.1 Experimental Resolution of Material Features -- 2.2 Grain Boundaries in Polycrystalline Materials -- 2.2.1 Grain Boundary Orientations

2.2.2 Dislocation Model of Low Angle Grain Boundaries -- 2.2.3 Grain Boundary Energy -- 2.2.4 Special Types of ``Low-Energy ́́Boundaries -- 2.2.5 Grain Boundary Dynamics -- 2.2.6 Representing Orientation Distributions in Polycrystalline Aggregates -- 2.3 Materials Processing and Microstructure -- 2.3.1 Conventional Solidification -- 2.3.2 Deformation Processing -- 2.3.3 Consolidation Processing -- 2.3.4 Thin-Film Formation -- 2.4 Microstructure and Materials Properties -- 2.4.1 Mechanical Properties -- 2.4.2 Transport Properties -- 2.4.3 Magnetic and Dielectric Properties

2.4.4 Chemical Properties -- 2.5 Microstructure Control and Design -- Practice Problems -- References -- Chapter 3 Crystal Structures and Binding Forces -- 3.1 Structure Description Methods -- 3.1.1 Close Packing -- 3.1.2 Polyhedra -- 3.1.3 The (Primitive) Unit Cell -- 3.1.4 Space Groups and Wyckoff Positions -- 3.1.5 Strukturbericht Symbols -- 3.1.6 Pearson Symbols -- 3.2 Cohesive Forces in Solids -- 3.2.1 Ionic Bonding -- 3.2.2 Covalent Bonding -- 3.2.3 Dative Bonds -- 3.2.4 Metallic Bonding -- 3.2.5 Atoms and Bonds as Electron Charge Density -- 3.3 Chemical Potential Energy

3.3.1 Lattice Energy for Ionic Crystals -- 3.3.2 The Born-Haber Cycle -- 3.3.3 Goldschmidt's Rules and Pauling's Rules -- 3.3.4 Total Energy -- 3.3.5 Electronic Origin of Coordination Polyhedra in Covalent Crystals -- 3.4 Common Structure Types -- 3.4.1 Iono-covalent Solids -- 3.4.2 Metal Carbides, Silicides, Borides, Hydrides, and Nitrides -- 3.4.3 Metallic Alloys and Intermetallic Compounds -- 3.5 Structural Disturbances -- 3.5.1 Intrinsic Point Defects -- 3.5.2 Extrinsic Point Defects -- 3.5.3 Structural Distortions -- 3.5.4 Bond Valence Sum Calculations

John Wiley and Sons Wiley Frontlist Obook All English 2020