|
| |||||||||||
| |||||||||||
Full Screen- TITLE
- CERTIFICATE
- DECLARATION
- ACKNOWLEDGEMENT
- CONTENTS
- PREFACE
- 1. A BRIEF REVIEW OF THE ELECTRICAL, OPTICAL AND STRUCTURAL STUDIES ON PHTHALOCYANINE THIN FILMS
- 1.1 Introduction
- 1.2 Organic Semiconductors
- 1.3 Molecular Structure
- Fig.1.3.2. Unit cell of a base centred phathalocyanine molecule
- 1.4 Electrical Studies
- 1.5 Optical Studies
- 1.6 Structural Studies
- References
- 2. APPARATUS AND EXPERIMENTAL TECHNIQUES
- 2.1 Introduction
- 2.2 Methods of Preparation of Thin Films
- 2.3 Thermal Evaporation Technique
- 2.4 Effect of Residual gases
- 2.5 Effect of Vapour Beam Intensity
- 2.6 Effect of Substrate Surface
- 2.7 Effect of Evaporation Rate
- 2.8 Contamination from Vapour Source
- 2.9 Purity of the Evaporating Materials
- 2.10 Production of vacuum
- 2.11 Oil Sealed Rotary Pump
- Fig.2.11 Schematic diagram of the cross section of an oilsealed rotary pump
- 2.12 Diffusion Pump
- Fig.2.12 Schematic diagram of the cross section of adiffusion pump
- 2.13 Vacuum Coating Unit
- Fig.2.13.1 Schematic diagram of a vacuum coating unit
- Fig.2.13.2 Schematic representation of Pirani gauge
- Fig. 2.13.3 Schematic representation of Penning gauge
- Fig.2.13.4 Photograph of the coating unit along with theaccessories
- 2.14 Preparation of Films
- 2.15 Substrate Cleaning
- 2.16 Substrate Heater
- 2.17 Sample Annealing
- Fig. 2.17.1 Block diagram of the temperature controller cumrecorder
- Fig. 2.17.2 Photograph of the furnace and controller cumrecorder set up
- 2.18 Thickness Measurement
- 2.19 Tolanskys Multiple Beam Interference Technique
- Fig.2.19 Schematic representation of the multiple beam interference technique
- 2.20 Conductivity Cell
- Fig. 2.20.1 Schematic diagram of the cross section of theconductivity cell
- 2.21 Keithley Programmable Electrometer 617
- Fig.2.21.l (a) Schematic diagram of measuring resistance onKeithley using ohms function
- Fig.2.21.2 Schematic diagram of electrical conductivitcgmeasurement (all dimensions are in mm)
- Fig.2.21.3 Photograph of the electrical conductivityexperimental set up
- 2.22 UV-Visible Spectrophotometer
- Fig. 2.22.1 Block diagram of the optical system ofSpedrophotometer (Shimadzu 160A)
- Fig. 2.22.2 Block diagram of the electrical system of the spectrophotometer
- Fig. 2.22.3 Photograph of the Shimadzu 160A Spectrophotometer
- 2.23 X-ray Diffractometer
- References
- 3. ELECTRICAL CONDUCTIVITY STUDIES ON LEAD PHTHALOCYANINE, ZINC PHTHALOCYANINE AND MAGNESIUM PHTHALOCYANINE THIN FILMS
- 3.1 Introduction
- 3.2 Theory
- 3.2.A Intrinsic Excitation
- 3.2.B Defect Excitation
- 3.2.C Injection of Carriers from Electrodes
- 3.2.D Band Model for Amorphous Materials
- 3.2.E Hopping Conduction
- 3.3. Experiment
- 3.4 Results and Discussion
- 3.4. A Dependence of Film Thickness
- 3.4. B Dependence of Substrate Temperature
- 3.4. C Dependence of Air-annealing
- 3.4. D Dependence of Vacuum-annealing
- 3.4.E Variable Range Hopping
- 3.5 Conclusion
- References
- 4. OPTICAL STUDIES ON LEAD PHTHALOCYANINE, ZINC PHTHALOCYANINE AND MAGNESIUM PHTHALOCYANINE THIN FILMS
- 4.1 Introduction
- Fig. 4.1 The schematic diagram of energy levels in metalphthalocyanine and the various allowed transitions
- 4.2 Theory
- 4.3 Experiment
- 4.4 Results and Discussion
- 4.5 Conclusion
- References
- 5. X-RAY DIFFRACTION STUDIES ON LEAD PHTHALOCYANINE, ZINC PHTHALOCYANINE AND MAGNESIUM PHTHALOCYANINE THIN FILMS
- 5.1 Introduction
- 5.2 Theory
- 5.3 Experiment
- 5.4 Results and Discussion
- 5.4.A Effect of Substrate Temperature
- 5.4.B Effect of Vacuum-annealing
- 5.5 Conclusion
- References
- 6. SUMMARY AND CONCLUSION