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  • TITLE
  • DECLARATION
  • ACKNOWLEDGEMENT
  • DEDICATION
  • ABSTRACT
  • PREFACE
  • List of Publications
  • CONTENTS
  • LIST OF TABLES
  • LIST OF FIGURES
  • LIST OF APPENDICES
  • 1. A BRIEF REVIEW ON THE TRIGONAL CRYSTALS CaCO3, Bi AND LiNbO3 AND AN INTRODUCTIONTO THE FINITE STRAIN ELASTICITY THEORY
  • 1.1 Introduction
  • 1.2 Calcite
  • 1.3 Bismuth
  • 1.4 Lithium Niobate
  • 1.5 The Theory of Elasticity
  • 1.6 Finite Strain Theory of Elasticity
  • References:
  • 2. KEATING’S APPROACH TO THE LATTICE DYNAMICS, SECOND AND THIRD-ORDER ELASTIC CONSTANTS AND PRESSURE DERIVATIVES OF THE SECOND-ORDER ELASTIC CONSTANTS OF TRIGONAL CRYSTALS
  • 2.1 Introduction
  • 2.2 Keating’s Approach to the Lattice Dynamics
  • 2.3 Calculation of the Second and Third-Order ElasticConstants by the Method of Homogeneous Deformation
  • 2.4 Calculation of the Pressure Derivatives of the Second-OrderElastic Constants of Trigonal Crystals
  • References:
  • 3. QUASI-HARMONIC THEORY OFTHERMAL EXPANSION AND THE LOWTEMPERATURE LIMIT γL OF THE GRUNEISEN FUNCTION
  • 3.1 Introduction
  • 3.2 Quasi-Harmonic Theory of Thermal Expansion
  • 3.3 Procedure to Calculate the Low Temperature Limit of the Gruneisen Function (y2)
  • References:
  • 4. SECOND-ORDER ELASTIC CONSTANTS, THIRD-ORDER ELASTIC CONSTANTS, PRESSURE DERIVATIVES OF THE SECOND-ORDER ELASTIC CONSTANTS AND LOW TEMPERATURE THERMAL EXPANSION OF CaCO3
  • 4.1 Introduction
  • 4.2 Second-Order Elastic Constants of CaCO3
  • Table 4.1Values of second-order potential parameters (in GPa) of CaCO3
  • Table 4.2Second-order elastic constants (in GPa) of CaCO3
  • 4.3 Third-Order Elastic Constants of CaCO3
  • Table 4.3Values of third-order potential parameters (in GPa) of CaCO3
  • Table 4.4Third-order elastic constants (in GPa) of CaCO3
  • 4.4 Pressure Derivatives of the Second-Order Elastic Constantsof CaCO3
  • Table 4.5Pressure derivatives of the second-order elasticconstants of CaCO3
  • 4.5 Generalized Gruneisen Parameters of Elastic Waves andLow Temperature Thermal Expansion
  • Table 4.6Generalized Gruneisen parameters of the elastic wavespropagating at different angles to the unique axis in CaCO3
  • Fig.4.1: Variation of the acoustic wave velocities with angle tothe unique axis of CaCO3.
  • Fig.4.2: Variation of the generalized Gruneisen parameters g ¢jwith angle for the different acoustic modes in CaCO3.
  • Fig.4.3: Variation of the generalized Gruneisen parameters g ¢j¢with angle for the different acoustic modes in CaCO3.
  • 4.6 Results and Discussion
  • References:
  • 5. SECOND-ORDER ELASTIC CONSTANTS, THIRD-ORDERELASTIC CONSTANTS, PRESSURE DERIVATIVES OF THESECOND-ORDER ELASTIC CONSTANTS AND LOWTEMPERATURE THERMAL EXPANSION OF TRIGONAL Bi
  • 5.1 Introduction
  • 5.2 Second and Third-Order Elastic Constants of Bi
  • Table 5.IValues of second-order potential parameters (in GPa) of Bi
  • Table 5.2Second-order elastic constants (in GPa) of Bi
  • 5.3 Third-Order Elastic Constants of Bi
  • Table 5.3Values of third-order potential parameters (in GPa) of Bi
  • Table 5.4Third-order elastic constants (in GPa) of Bi
  • 5.4 Pressure Derivatives of the Second-Order Elastic Constantsof Bi
  • Table 5.5Pressure derivatives of the second-order elastic constants of Bi
  • 5.5 Generalized Gruneisen Parameters of Elastic Waves andLow Temperature Thermal Expansion
  • Table 5.6Generalized Gruneisen parameters of the elastic wavespropagating at different angles to the unique axis in Bi
  • Fig.5.1: Variation of the acoustic wave velocities with angle tothe unique axis of Bi
  • Fig.5.2: Variation of the generalized Gruneisen parameter j g ¢ withangle for the different acoustic modes in Bi
  • Fig.5.3: Variation of the generalized Gruneisen parameter j g ¢¢ withangle for the different acoustic modes in Bi
  • 5.6 Results and Discussion
  • References
  • 6. SECOND-ORDER ELASTIC CONSTANTS, THIRD-ORDER ELASTIC CONSTANTS, PRESSURE DERIVATIVES OF THE SECOND-ORDER ELASTIC CONSTANTS AND LOW TEMPERATURE THERMAL EXPANSION OF TRIGONAL LiNbO3
  • 6.1 Introduction
  • 6.2 Second-Order Elastic Constants
  • Table 6.1Values of second-order potential parameters (in GPa) of LiNbO3
  • Table 6.2Second-order elastic constants (in GPa) of LiNbO3
  • 6.3 Third-Order Elastic Constants
  • Table 6.3Values of third-order potential parameters (in GPa) of LiNbO3
  • Table 6.4Third-order elastic constants (in GPa) of LiNbO3
  • 6.4 Pressure Derivatives of the Second-Order Elastic Constants
  • Table 6.5Pressure derivatives of the second-order elastic constants ofLiNbO3
  • 6.5 Generalized Gruneisen Parameters of Elastic Waves andLow Temperature Thermal Expansion
  • Table 6.6Generalized Gruneisen parameters of the elastic wavespropagating at different angles  to the unique axis in LiNbO3
  • Fig.6.1: Variation of the acoustic wave velocities with angle tothe unique axis of LiNbO3
  • Fig.6.2: Variation of the generalized Gruneisen parameters j g ¢ withangle for the different acoustic modes in LiNbO3
  • Fig.6.3: Variation of the generalized Gruneisen parameters j g ¢¢with angle for the different acoustic modes in LiNbO3
  • 6.6 Results and Discussion
  • References:
  • 7. SUMMARY AND CONCLUSION
  • References
  • APPENDIX I Position co-ordinates of the Three nearest neighbours of the different atoms in the unit cell of CaCO3
  • APPENDIX II Position co-ordinates of the Three nearest neighbours of the different atoms in the unit cell of Bi
  • APPENDIX III Position co-ordinates of the Three nearest neighbours of the different atoms in the unit cell of LiNbO3