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Full Screen- TITLE
- DECLARATION
- CERTIFICATE
- ACKNOWLEDGEMENT
- CONTENTS
- PREFACE
- 1. THEORY OF CONDUCTIVITY AND DIELECTRICS
- 1.1 Introduction
- 1.1.1 Anisotropic Conduction
- 1.2 Dielectrics
- 1.2.1 Measurement of Dielectric Tensor
- 1.3 Conductivity Measurement Theory
- 1.3.1 Theory of DC Conductivity
- 1.4 DC Conductivity Measurement Methods
- 1.4.1 General Methods of Measurements
- 1.4.2 Ohmmeter and Voltmeter -Ammeter Measurements
- 1.4.3 Potential Probe Method
- 1.4.4 Spreading Resistance Method
- 1.4.5 Four- Point Probe Method
- 1.4.6 Electrometer Method
- 1.5 Theory of Dielectrics and AC Conductivity
- 1.5.1 Dielectric Materials
- 1.5.2 General Theory
- 1.5.3 Behaviour of Dielectrics in Time Varying Field
- 1.5.4 Complex Plane Analysis
- 1.6 Dielectric Spectra Analysis
- 1.6.1 Equivalent Circuit analysis
- 1.6.2 Theoretical aspect of Cole- Cole plot
- 1.6.3.Dielectric relaxation
- 1.6.4 Static and optic dielectric constant
- 1.6.5 Interpretation of the Dielectric Behaviour
- 1.7 Electrode effects on the measurements of dielectric properties
- 1.8 Dielectric spectroscopy-Outlook
- 1.9 Theory of Phase Transition
- 1.9.1 Introduction
- 1.9.2 Order of Phase Transition
- 1.9.3 Landau Theory of Phase Transition
- References
- 2. EXPERIMENTAL TECHNIQUES
- 2.1 Introduction
- 2.2 Conductivity Measurement Methods
- 2.2.1 DC Electrical Conductivity Measurements.
- 2.2.2 Alternating Current Bridge Method
- 2.3 The fabricated Conductivity Cell
- Fig 2.6: The fabricated conductivity cell
- 2.4 DC Conductivity Measurements
- 2.5 AC Conductivity Measurements
- 2.5.1 Conducting an Impedance Spectroscopy Experiment
- Fig 2.8: DC conductivity measurement setup
- Fig 2.9: AC conductivity and dielectric measurement setup
- 2.6 Sample Preparation
- 2.6.1 Crystal Growth from Solution
- 2.7 Constant Temperature Bath
- Fig 2.10: An overview of the constant temperature bath
- Fig 2.11: Photograph of the crystal growth setup
- 2.8 Designed Temperature Controller
- 2.9 Identification of the Faces using Stereographic Projection
- Fig 2.15: A crystal model with (111) face
- 2.10 Crystal Cutting and Polishing
- Fig 2.19: Photograph of the crystal polishing unit
- References
- 3. DC ELECTRICAL CONDUCTIVITY AND PHASE TRANSITION STUDIES OF LITHIUM HYDRAZINIUM SULPHATE SINGLE CRYSTAL
- 3.1 Literature Review
- Fig 3.1: Unit cell visualization of LHS crysta in the a- b plane
- Fig 3.2: Morphology of the LHS crystal
- 3.2 Experimental Details
- 3.2.1 Crystal Growth
- 3.2.2 Cutting and Polishing
- 3.2.3 Measurements of DC Conductivity
- Fig 3.5: Photograph of the Grown LHS crystal
- Fig 3.6: Stereographic projection of LHS crystal projected at 001 direction
- 3.3 Results and Discussion
- 3.3.1 DC Conductivity Along a, b and c- axes
- 3.4 Discussion
- 3.5 Conclusion
- References
- 4. AC ELECTRICAL CONDUCTIVITY, DIELECTRIC AND PHASE TRANSITION STUDIES OF LITHIUM HYDRAZINIUM SULPHATE SINGLE CRYSTAL
- 4.1 Introduction
- 4.2 Experimental
- 4.3 Results and Discussion
- 4.3.1 Complex Impedance Analysis along a-axis
- 4.3.2 Complex Impedance Analysis along b-axis
- 4.3.3 Complex Impedance Analysis along c-axis
- 4.4 Dielectric Analysis
- 4.4.1 Frequency dependant dielectric spectra
- 4.4.2 Temperature dependence of dielectric constant
- 4.5 Conductivity Analysis
- 4.5.1 Frequency dependent conductivity spectra
- 4.5.2 Temperature dependent AC conductivity
- 4.6 Conclusion
- References
- 5. DC ELECTRICAL CONDUCTIVITY AND PHASE TRANSITION STUDIES OF LITHIUM HYDROXYLAMMONIUM SULPHATE SINGLE CRYSTAL
- 5.1 Literature Review
- 5.2 Sample Preparation
- 5.2.1 Crystal Growth
- Fig5.1: Unit cell visualization of LHAS crystal in the a c plane. Unit cell containing 8 molecules.
- Fig 5.4: Stereographic projection of the LHAS crystal projected at 100 direction. The possible grown faces are shown
- 5.2.2 X-ray Powder diffraction pattern of LHAS crystal
- 5.2.3 Cutting and Polishing
- 5.3 Measurements of DC Conductivity
- 5.4 Results and Discussion
- 5.4.1 DC Conductivity in the low temperature region
- 5.4.2 DC Conductivity in the high temperature region
- 5.5 Thermogravimetric analysis
- 5.6 Conclusion
- References
- 6. AC ELECTRICAL CONDUCTIVITY, DIELECTRIC AND PHASE TRANSITION STUDIES OF LITHIUM HYDROXYLAMMONIUM SULPHATE SINGLE CRYSTAL
- 6.1 Introduction
- 6.2 Sample Preparation
- 6.3 Complex Impedance Analysis of LHAS
- 6.3.1 Complex Impedance analysis along a-axis
- 6.3.2 Complex Impedance analysis along c-axis
- 6.4 Dielectric Analysis
- 6.4.1 Frequency dependant dielectric spectra along a and c-axes
- 6.4.2 Temperature dependant dielectric spectra in the low temperature region.
- 6.4.3 Temperature dependant dielectric spectra in the high temperature region
- 6.5 Conductivity Analysis
- 6.5.1 Frequency dependent conductivity spectra along a and c-axes
- 6.5.2 Temperature dependent conductivity spectra in the low temp. region
- 6.5.3 Temperature dependent conductivity spectra in the high temp. region.
- 6.6 Conclusion
- References
- 7. DC CONDUCTIVITY AND PHASE TRANSITION STUDIES OF SULFURIC ACID SINGLE CRYSTAL
- 7.1 Literature Review
- 7.2 Experimental Details
- 7.2.1 Crystal Growth
- Fig 7.1; Arrangement of eight molecules in the unit cell of Sulphamic acid
- Fig 7.2: Morphology of the Sulphamic acid single crystal
- Fig 7.3: Photograph of the grown Sulphamic acid crystal. - picture shows the crystal was cut inthe c plane
- Fig 7.4 & 7.5: Stereographic projection projected at 100 &001
- 7.2.2 Cutting and Polishing
- 7.3 Measurements of DC Conductivity
- 7.4 Results and Discussion
- 7.4.1 DC Electrical conductivity along a, b, and c-axes in the low temp. region
- 7.4.2 DC Conductivity in the high temperature region
- 7.5 Conclusion
- References
- 8. INVESTIGATION OF PHASE TRANSITION IN SULPHAMIC ACID SINGLE CRYSTAL USING AC CONDUCTIVITY AND DIELECTRIC STUDIES
- 8.1 Introduction
- 8.2 Experimental Details
- 8.3 Dielectric Analysis
- 8.3.1 Frequency dependant dielectric spectra in the low temperature region.
- 8.3.2 Frequency dependant dielectric spectra in the high temperature region.
- 8.3.3 Temperature dependant dielectric spectra in the low temperature region
- 8.3.4 Temperature dependant dielectric spectra in the high temperature region
- 8.4 Conductivity Analysis
- 8.4.1 Frequency dependent conductivity spectra
- 8.4.2 Temp dependent ac conductivity spectra in the low temperature region
- 8.4.3 AC conductivity spectra in the high temperature region
- 8.5 Conclusion
- References
- 9. DC CONDUCTIVITY AND PHASE TRANSITION STUDIES OF POTASSIUM SULPHATE SINGLE CRYSTAL
- 9.1 Literature review
- 9.2 Experimental Details
- 9.2.1 Crystal Growth
- Fig.9.1 Arrangements of molecule in the unit cell.
- Fig.9. 2: Morphology of potassium sulphamate crystal
- Fig 9.3: Photograph of the grown crystal.
- Fig 9.4: Stereographic projection of potassium sulphamate crystal projected at 100
- 9.2.2 Cutting and Polishing
- 9.3 Results of DC conductivity in the low temperature region
- 9.4 Results of DC conductivity in the high temperature region
- 9.5 Conclusion
- Reference
- 10. INVESTIGATION OF PHASE TRANSITION IN POTASSIUM SULPHAMATE SINGLE CRYSTAL: AC ELECTRICAL CONDUCTIVITY AND DIELECTRIC STUDIES
- 10.1 Introduction
- 10.2 Experimental
- 10.3 Results and Discussion
- 10.3.1 Complex Impedance analysis along a- axis
- 10.3.2 Complex Impedance analysis along b- axis
- 10.3.3 Complex Impedance analysis along c- axis
- 10.4 Dielectric Analysis
- 10.4.1 Frequency dependant dielectric spectra
- 10.4.2 Temperature dependant dielectric spectra in the low temperature region.
- 10.4.3 Temperature dependant dielectric spectra in the high temperature region.
- 10.5 Conductivity Analysis
- 10.5.1 Frequency dependent conductivity spectra along a, b and c- axes
- 10.5.2 Temperature dependant Conductivity spectra along a, b and c-axes in the temperature region 243 K- 303K:
- 10.5.3 Temperature dependant Conductivity spectra along a, b and c-axes in the temperature region 303K-450K
- 10.6 Conclusion
- References
- CONCLUDING REMARKS AND FUTURE OUTLOOK