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Crystal growth : theory, mechanisms, and morphology /
| Clasificación: | Libro Electrónico |
|---|---|
| Otros Autores: | , |
| Formato: | Electrónico eBook |
| Idioma: | Inglés |
| Publicado: |
New York :
Nova Publishers,
[2012]
|
| Colección: | Physics research and technology.
Materials science and technologies series. |
| Temas: | |
| Acceso en línea: | Texto completo |
Tabla de Contenidos:
- CRYSTAL GROWTH ; CRYSTAL GROWTH ; Contents; Preface; Supersaturation: Formation, Measurement and Control; Abstract; I. Introduction; II. Varied Systems and the Ways to Generate Supersaturation in Them. (Methods and Apparatus for Crystallization); III. Systems in which Temperature Dependence of Solubility is Used to Attain Supersaturation; Preparation of High Purity Starting Material KB5; Growing of Single KB5 Crystals; IV. Method of Supersaturation Formation by Chemical Reaction.
- V. Methods of Indirect Measurement of Supersaturation by Using Various Concentration Dependent Solution ParametersInterferometric Technique; Density (Specific Gravity); Electrical Conductivity; Delta T Sensor and Surface Acoustic Wave; Potentiometric Method; Fluorescent Spectra; Formation and Measuring of Supersaturation by Pressure; Calculation in Case of AIIBVI Compounds (CdS); Prediction Mode; Recent Advances in the in-situ Measurement Technology and Automation, Using Raman Spectra and Antisolvent Addition Method; Conclusion; References.
- Self-Assembly of Epitaxial III/V-Compound Semiconductor Quantum DotsAbstract; 1. Introduction; 2. Strain-InducedInAsQDs; 2.1. MechanismofStrain-InducedQDFormation; 2.2. InAsQDOptoelectronicalProperties; 3. DropletEpitaxialGaAsQDs; 3.1. DensityandShapeofDropletEpitaxialQDs; 3.2. OpticalPropertiesofDropletEpitaxialQDs; 4. GaAsQDsFormedbyFillingofSelf-assembledNanoholes; 4.1. StructuralPropertiesofLDENanoholesandRings; 4.2. FabricationofQDsbyFillingofLDENanoholes; 5. Conclusions; Acknowledgments; References; Theory of Kinetic Experiment at Crystal Growth from Solutions in Melts; Abstract; Introduction.
- 1. Conception of a Kinetic Experiment2. Driving Force of Interphase Processes; 3. Thermomigration Process; 4. Mathematical Model of Non-stationary Thermomigration of Flat Interlayer; 5. Fast-Response Heating Systems. First Type of Nonstationarity; 5.1. Transient Process in a Layer of a Solution in a Melt: Change in Limiting Stage of Mass Transfer; 5.2. Small Temperature Oscillations Effect on the Characteristic Size Dependence of Migration Velocity; 5.3. Non-Stationary Thermomigration. The Characteristic Size Dependence of Migration Velocity in the Case of Non-Stationary Thermomigration.
- 6. Second Type of Nonstationarity. Slow-Response Heating System6.1. Temperature Change with Constant Rate. Lemma on Velocity of Middle Section of Liquid Layer; Statement; Proof; 6.2. The Characteristic Size Dependence of Migration Velocity in the Case of Slow Temperature Changes with Constant Rate; 7. Thermal Stationarity Criteria. Choice of Mass Transfer Mode for Kinetic Experiment; 8. Experimental Determination of Diffusive Velocity and Total Supersaturations; Conclusion; Referenses; Growth of InN and In-rich Group III-nitride Alloys in Cubic Phase; Abstract; I. Introduction.