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Physical Basis of Plasticity in Solids.
This book introduces the physical mechanism of the plastic deformation of solids, which relies essentially on the occurrence and motion of dislocations. These are linear defects, specific of crystalline solids whose motion under external stresses explains the relative ease by which solids (metals in...
| Clasificación: | Libro Electrónico |
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| Autor principal: | |
| Formato: | Electrónico eBook |
| Idioma: | Inglés |
| Publicado: |
Singapore :
World Scientific,
2011.
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| Temas: | |
| Acceso en línea: | Texto completo |
Tabla de Contenidos:
- Preface; Contents; 1. Introduction; 1.1 Plasticity; 1.1.1 Mechanical properties of solids; 1.1.2 Microscopic mechanisms; Elastic behaviour; Plastic behaviour; 1.2 Organization and contents of the chapters; 1.3 General References; 2. The structure of crystalline solids; 2.1 Introduction; 2.2 Crystal geometry; 2.2.1 Ideal crystal; 2.3 Bravais lattices; 2.3.1 Definition; 2.3.2 Properties; Non-unicity of the generating translations; Lattice planes and rows; Symmetry of the Bravais lattice; Constraints on the rotation angles; 2.4 Unit cells; 2.4.1 Primitive unit cells.
- 2.4.2 Conventional unit cells2.4.3 Classification of the Bravais lattices. Cubic lattices; a) Simple cubic lattice (abbreviated as SC); b) Body centered cubic lattice (abbreviated as BCC); c) Face centered cubic lattice (abbreviated as FCC); 2.5 Examples of crystal structures; 2.5.1 Simple monoatomic structure packings; Cubic close-packing; Hexagonal close-packing; Relationship between close-packings; Body centered cubic packing; 2.5.2 Physical realizations in metals; Metallic alloys; 2.5.3 Simple covalent structures; 2.6 Non-crystalline solids; 3. Mechanics of deformable solids.
- 3.1 Introduction3.2 Fundamental tensors; 3.2.1 Strain and stress; 3.2.2 Stiffness; 3.3 Coordinate changes; 3.4 Stiffness tensor and crystal symmetry; 3.4.1 General constraints; 3.4.2 Crystal symmetry; 3.4.3 Mathematical transformation of tensors; 3.5 Isotropic solids; 3.5.1 Stiffness tensor; 3.5.2 Basic equations; 4. Vacancies, an example of point defects in crystals; 4.1 Classification of defects in crystals; 4.2 Stability of point-defects in solids; 4.2.1 Statistical equilibrium; 4.2.2 Concentration of defects at thermal equilibrium; 4.3 Formation of vacancies; 4.3.1 Formation energy.
- Description of the elastic modelDisplacement field; Induced strain and stress; Elastic energy of a vacancy; Energy of a vacancy in a metal; 4.3.2 Random displacement of vacancies, diffusion; Frequency of jumps; Average free path of the vacancies; Macroscopic diffusion of vacancies; Self-diffusion of atoms; Other types of point defects; 5. The geometry of dislocations; 5.1 Introduction; 5.2 Straight edge dislocation; 5.2.1 Hypothetical procedures of formation; Addition or substraction of a half atomic plane; Formation by partial slipping; Amplitude of the slipping and primitive translations.
- General definition of a dislocation5.2.2 Burgers circuit and Burgers vector; Burgers circuit; Sign of the Burgers vector of an edge dislocation; Physical meaning of the Burgers vector; 5.2.3 Edge dislocation loops; Rectangular loop; Dislocation-loop of arbitrary shape; 5.3 Other types of dislocations; 5.3.1 Screw dislocation; Formation by slipping; Burgers vector; 5.3.2 Mixed dislocation-loops; 5.3.3 General properties of the Burgers vector; 5.4 Volterra process of formation; 5.4.1 Edge and screw dislocations; Edge-dislocation formed by slipping.