Crystals and crystal growth
Crystal growth Crystallography Crystals SCIENCE / Physics / Crystallography sähkökirjat
Nova Science Publishers, Inc.
2014
EISBN 9781634638227
CRYSTALS AND CRYSTAL GROWTH; CRYSTALS AND CRYSTAL GROWTH; Library of Congress Cataloging-in-Publication Data; Contents; Preface; Chapter 1: Hydrothermal Crystal Growth from SiO2.
GeO2 Solid Solution for Piezoelectric Applications; CNRS, Université de Bordeaux, ICMCB, Pessac, France; Abstract; 1. Introduction; 2. Historical Aspects of Hydrothermal Crystal Growth; 3. Hydrodynamic Aspects of Hydrothermal Crystal Growth; 4. Hydrothermal Solvent Behaviour; 5. Crystal Growth by Hydrothermal; 6. (-Quartz -General Properties and Applications; 7. Germanium Oxide (GeO2) Crystal Structure
4. Crystal Elongation Dueto Macromolecules Additives; Conclusion; References; Index
8. SiO2-GeO2Based Single Crystals by Hydrothermal MethodConclusion; References; Chapter 2: In-Situ Investigation of the Melt Structures in Borate Crystal Growth Systems; Abstract; 1. Introduction; 2. High-Temperature Raman Spectroscopy; 3. The Density Functional Theory Method; 4. Melt Structures in Some Borate Crystal Growth Systems; (1) Melt Structures in the Ba2Mg(B3O6)2 and BaB2O4 Crystal Growth Systems; (2) Melt Structures in the CsB3O5 and LiB3O5 Crystal Growth Systems; (3) The Melt Structure in the BiB3O6 Crystal Growth System; (4) The Melt Structure in the Li2B4O7 Crystal Growth System
ConclusionAcknowledgments; References; Chapter 3: Doped Organic Crystals with High Efficiency, Color-Tunable Emission toward Laser Application; Abstract; Introduction; Morphology and Structure of the Crystals; Optical Properties; Amplified Spontaneous Emission Experiment; White-Light Emissive Doped Crystal; and Time-Resolved Properties; Conclusion; References; Chapter 4: Modeling Effects of Impurities on Crystal Growth; Abstract; 1. Introduction; 2. Distribution Coefficient of Impurity; 3. Modeling Impurity Effects; 3.1. Kubota-Mullin Model; 3.2. Birth and Spread Model
Hydrothermal crystal growth offers a complementary alternative to many of the classical techniques of crystal growth used to synthesize new materials and grow bulk crystals for specific applications. This specialized technique is often capable of growing crystals at temperatures well below their melting points and thus potentially offers routes to new phases or the growth of bulk crystals with less thermal strain. Borate crystals are widely used as nonlinear optical, laser and luminescent materials due to their diversified structures, and good chemical and physical properties. The growth of hi.
GeO2 Solid Solution for Piezoelectric Applications; CNRS, Université de Bordeaux, ICMCB, Pessac, France; Abstract; 1. Introduction; 2. Historical Aspects of Hydrothermal Crystal Growth; 3. Hydrodynamic Aspects of Hydrothermal Crystal Growth; 4. Hydrothermal Solvent Behaviour; 5. Crystal Growth by Hydrothermal; 6. (-Quartz -General Properties and Applications; 7. Germanium Oxide (GeO2) Crystal Structure
4. Crystal Elongation Dueto Macromolecules Additives; Conclusion; References; Index
8. SiO2-GeO2Based Single Crystals by Hydrothermal MethodConclusion; References; Chapter 2: In-Situ Investigation of the Melt Structures in Borate Crystal Growth Systems; Abstract; 1. Introduction; 2. High-Temperature Raman Spectroscopy; 3. The Density Functional Theory Method; 4. Melt Structures in Some Borate Crystal Growth Systems; (1) Melt Structures in the Ba2Mg(B3O6)2 and BaB2O4 Crystal Growth Systems; (2) Melt Structures in the CsB3O5 and LiB3O5 Crystal Growth Systems; (3) The Melt Structure in the BiB3O6 Crystal Growth System; (4) The Melt Structure in the Li2B4O7 Crystal Growth System
ConclusionAcknowledgments; References; Chapter 3: Doped Organic Crystals with High Efficiency, Color-Tunable Emission toward Laser Application; Abstract; Introduction; Morphology and Structure of the Crystals; Optical Properties; Amplified Spontaneous Emission Experiment; White-Light Emissive Doped Crystal; and Time-Resolved Properties; Conclusion; References; Chapter 4: Modeling Effects of Impurities on Crystal Growth; Abstract; 1. Introduction; 2. Distribution Coefficient of Impurity; 3. Modeling Impurity Effects; 3.1. Kubota-Mullin Model; 3.2. Birth and Spread Model
Hydrothermal crystal growth offers a complementary alternative to many of the classical techniques of crystal growth used to synthesize new materials and grow bulk crystals for specific applications. This specialized technique is often capable of growing crystals at temperatures well below their melting points and thus potentially offers routes to new phases or the growth of bulk crystals with less thermal strain. Borate crystals are widely used as nonlinear optical, laser and luminescent materials due to their diversified structures, and good chemical and physical properties. The growth of hi.
