Cargando…
Physics of radiation effects in crystals /
``Physics of Radiation Effects in Crystals'' is presented in two parts. The first part covers the general background and theory of radiation effects in crystals, including the theory describing the generation of crystal lattice defects by radiation, the kinetic approach to the study of the...
| Clasificación: | Libro Electrónico |
|---|---|
| Otros Autores: | , |
| Formato: | Electrónico eBook |
| Idioma: | Inglés |
| Publicado: |
Amsterdam ; New York : New York :
North-Holland ; Sole distributors for the U.S.A. and Canada, Elsevier Science,
1986.
|
| Colección: | Modern problems in condensed matter sciences ;
v. 13. |
| Temas: | |
| Acceso en línea: | Texto completo Texto completo |
Tabla de Contenidos:
- Front Cover; Physics of Radiation Effects in Crystals; Copyright Page; PREFACE TO THE SERIES; PREFACE; Table of Contents; PART I; CHAPTER 1. Basic Defects in Metals; Introduction; 1. Theory of point defects; 2. Experimental methods; 3. Results for point defects in metals; Acknowledgements; References; CHAPTER 2. Production of Radiation Defects by Collision Cascades in Metals; 1. Introduction; 2. Formation of primary knock-on atoms; 3. Radiation damage dynamics; 4. Radiation damage dynamics at high energies; 5. Radiation damage dynamics in crystals with defects
- 6. Radiation damage of amorphous metalsReferences; CHAPTER 3. Theory of Microstructural Evolution; 1. Introduction; 2. Fundamental considerations; 3. Mathematical rate theory; 4. Simulation of neutron damage; 5. Conclusions; References; CHAPTER 4. Phase Stability and Solute Segregation during Irradiation; 1. Introduction; 2. Kinetic processes; 3. Effects on equilibration and on redistribution of phases; 4. Radiation-induced nonequilibrium phases; 5. Effects of irradiation on near surface structure and composition; Acknowledgements; References; PART II
- CHAPTER 5. Quasichemical Reactions Involving Point Defects in Irradiated Semiconductors1. Introduction; 2. Formation of primary defects; 3. Diffusion of primary defects; 4. Reactions involving vacancies V, interstitial atoms I, and impurities F; 5. Reactions between point defects in inhomogeneous systems; References; CHAPTER 6. Radiation Damage and Stress Effects in Superconductors: Materials for High-Field Applications; 1. Introduction; 2. NbTi; 3. A15 Compounds; 4. Summary; References; CHAPTER 7. Radiation Effects in Non-Metals; 1. Introduction; 2. The primary damage event
- 3. Secondary defect kinetics4 . Structural effects; 5. Electrical and optical effects; 6. Practical considerations; 7. Summary; Acknowledgements; References; CHAPTER 8. Creation of Frenkel Defect Pairs by Excitons in Alkali Halides; 1. Introduction; 2. Electronic excitations; 3. Point defects; 4. Creation of long-lived anion defects by radiation; 5. Recombination of complementary Frenkel defects; 6. Tunnelling recharge and aggregation of defects; 7. Short-lived radiation defects; 8. Mechanisms of exciton decay with defect creation; 9. Concluding remarks; Acknowledgements; References
- List of symbols and abbreviationsCHAPTER 9. Irradiation Growth of Metals and Alloys; 1. Introduction; 2. General characteristic; 3. Simulation studies of the irradiation growth of metals and alloys; 4. Mechanism of irradiation growth; 5. Conclusions; References; CHAPTER 10. Irradiation Creep of Metals; Introduction; Part I: A set of equations used to describe irradiation creep; 1. Equations for point defect motion in a crystal; 2. Rate equations for point defect concentrations; 3. Boundary concentrations of point defects; 4. A flux of point defects into sinks; 5. Conclusions to Part I