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Full Screen- TITLE
- DEDICATION
- CERTIFICATE
- DECLARATION
- ACKNOWLEDGEMENT
- CONTENTS
- PREFACE
- 1. CONDUCTING POLYMERS - AN INTRODUCTION
- 1.1.Introduction
- 1.2.Historical background of the development of conducting polymers
- 1.3.Mechanism of electrical conduction in conducting polymers
- 1.4.Chemical synthesis of conducting polymers
- 1.4.1. Polyacetylene
- 1.4.2. Polypara phenylene sulphide
- 1.4.3. Polypara phenylene
- 1.4.4. Polypyrrole
- 1.5.Electrochemical synthesis
- 1.6.Doping methods
- 1.7.Effect of doping on polymers
- 1.8.Stable and processable conducting polymers
- 1.9Electrochemical property-Cyclic voltammetry
- 1.10.Progress towards technology
- 1.11.Work undertaken in the present study
- References
- 2. PREPARATION AND CHARACTERIZATION OF CONDUCTING POLYPYRROLES
- 2.1.General introduction
- 2.2.Chemical oxidative polymerization of polypyrrole
- 2.3.Electrochemical polymerization of polypyrrole
- 2.4.Mechanism of electrochemical polymerization
- 2.5.Experimental set-up for the electrochemical polymerization of polypyrrole films
- Fig.2.1 shows a single compartmentelectrolytic cell used for the polymerization of pyrrole.
- Fig.2.2 Schematic diagram of two compartment cell used fort.he polymerization reaction of pyrrole
- 2.6.Characterization of polypyrroles
- 2.6.1. UV-visible spectroscopy
- 2.6.2. Infrared spectroscopy
- 2.6.3. Scanning electron microscopy (SEM)
- 2.6.4. Cyclic voltammetry studies
- 2.6.5. TG and DTA studies
- 2.6.6. Ultrasonic studies
- 2.6.7. X-ray analysis
- References
- 3. SYNTHESIS OF CERTAIN CONDUCTING POLYPYRROLES AND STUDY OF THEIR DC CONDUCTIVITY
- 3.1.Introduction
- Table 3.1. Common dopants for polymers.
- 3.2.Experimmental set-up for conductivity measurements
- 3.2.1. Four point probe method
- Fig.3.1. Experimental set-up for four proberesistivity measurement.
- 3.2.2. Two probe method
- 3.3.Conductivity cell
- Fig.3.2.Cross sectional view of the conductivity cell.
- 3.4.Keithly electrometer
- 3.5.Work Included in this chapter
- Fig.3.3. Circuit diagram of two probe set-up.
- Section A
- 3.6.Electrochemical synthesis of conducting polypyrrole films using ammonium molybdate and traces of sulphuric acid as electrolyte and study of their DC conductivity
- 3.6.1. Introduction
- 3.6.2. Experiemental details
- 3.6.3. Measurement of electrical conductivity
- 3.6.4. Results and discussion
- Table 3.3 Effect of NaOH aqueous solution treatment on conductivity
- Table 3.4Effect of temperature on the film conductivity for variousfilm thickness at a current of 3 mA
- Table 3.5Change of conductivity as a function of current density
- Fig.3.4 Scanning electron micrographs of PPy (MoO4) 2- films prepared at various currentn densities.
- 3.6.5. Effect of the treatment of PPy (MoO) 2 films with aqueous sodium hydroxide solution on their electrical conductivity
- Table 3.7Effect of current density on conductivity
- 3.6.6. Effect of alternate treatment with base and acid on conductivity
- Fig.3.5.Effect of alternate treatment wit5-base andacid on conductivity of PPy (MoO4) 2-)
- Section B
- 3.7.Electrochemical synthesis of polypyrrole films using molybdic acid as an electrolyte and investigation of their DC conductivity
- 3.7.1. Introduction
- 3.7.2. Experimental
- 3.7.3. DC conductivity measurements
- 3.7.4. Results and discussion Effect of the treatment of PPy (Mo0) 2
- 3.7.5. films with aqueous sodiumm hydroxide solution on their electrical conductivity
- 3.7.6. Effect of alternate treatement with base and acid on conductity.
- Section C
- 3.8.Electrochemical synthesis of polypyrrole films using molybdic acid as an electrolyte and investigation of their DC conductivity
- 3.8.1. Introduction
- 3.8.2. Experimental
- 3.8.3. Results and discussion
- 3.8.4. Effect of the treatment of PPy (Mo04) 2 films with aqueous sodium hydroxide solution on their electrical conductivity
- Table 3.8Effect of the temperature on the film conductivity
- 3.8.5. Effect of alternate treatment with base and acid on conductivity
- Fig.3.7.Effect of alternate treatment with base and acid on the conductivity of PPy (P0 4)
- Section D
- 3.9.Chemical polymerization of pyrrole using orthophosphoric acid and investigation of DC conductivity of polypyrrole films
- 3.9.1. Introdution
- 3.9.2. Experimental details
- 3.9.3. Results and discussion
- Table 3.10Variation of conductivity of pressed pelletswith temperature
- Section E
- 3.10.Preparation of characterization of a chemically prepared polypyrrole powder, soluble in acetone, an organic solvent
- 3.10.1. Introdution
- 3.10.2. Experimental details
- 3.10.3. DC conductivity studies
- 3.10.4. Results and discussion
- CONCLUSION
- References
- 4. INFRARED SPECTROSCOPY STUDIES
- 4.1.General Introduction
- 4.2.IR spectroscopy of polymers
- 4.3. Interpretation of spectra
- 4.3.1. Hetero aromatic compounds
- 4.3.2. C-H stretching vibrations
- 4.3.3. N-H stretching vibrations
- 4.3.4. Ring stretching vibrations
- 4.3.5. C-H out-of-plane bending
- 4.4.Work included in this chapter
- 4.5.Experimental details
- 4.6.Results and discussion Infrared spectra of PPy (Mo0) 2
- 4.6.1.films prepared electrochemically using aqueous solution of ammonium molybdate and trace at H SO4 as the electrolyte
- Fig.4.1. IR spectrum of PPy (MoO4) 2 - prepared using aqueous solution of amonium molybdate and H2SO4 as electrolyte.
- Table 4.1 Assignment of IR spectra
- Fig.4.2. IR spectra of PPy (MoO4) 2- film prepared electrochemically at 5 c
- Table 4.2 Assignment of IR spectra
- 4.6.2. Infrared spectra of PPy (Mo0) 2 films prepared electrochemically using aqueous solution of molybdic as the electrolyte
- Fig.4.3. IR spectra of PPy (MoO4) 2- sample prepared using aqueous solution of molybdate acid as the electrolyte.
- Table 4.3Assignment of IR spectra
- 4.6.3. Infrared spectra of PPy (PO4) films prepared electrochemically using aqueous solution of orthophosphoric acid as the electrolyte
- 4.6.4. FTIR spectra of PPy (PO) films prepared chemically using orthophosphoric acid in acetonitrile as the oxident acid in acetonitrile as the oxident
- Fig.4.4. IR spectra of PPy (PO4) 3- film prepared at room temperature.
- Table 4.4 Assignment of IR spectra
- Fig.4.5. FTIR spectra of PPy (P0) film prepared chemically using H3PO4 in acetonitrile as oxident.
- Table 4.5Assignment of FTIR spectra
- 4.6.5. FTIR spectra of PPy (PO) powder prepared chemically using orthophosphoric acid in acetone as the oxident
- Fig.4.6. FTIR spectra of PPy (PO4) powder, using orthophosphoric acid in acetone as oxident.
- Table 4.6 Assignment of FTIR spectra
- CONCLUSION
- References
- 5. ULTRAVIOLET-VISIBLE SPECTROSCOPY STUDIES
- 5.1.Introduction
- 5.2.Experimental
- 5.3.Results and discussion
- Fig.5.1.UV-visible spectrum of PPy (MoO4) 2- prepared by electrochemical method.
- Fig.5.2 UV-visible spectrum of PPy (MoO4) film prepared by electrochemical method using aqueous solution of molybdic acid.
- Fig.5.3.UV-visible spectrum of PPy (PO4) 3- prepared by electrochemical method using aqueous solution of orthophosphoric acid as the electrolyte.
- Fig.5.4.UV-visible spectrum of PPy (PO4) film synthesized chemically using H3PO4 and acetonitrile
- Fig.5.5.UV-visible spectrum of PPy (PO4) powder synthesized chemically using H3PO4 and acetone.
- CONCLUSION
- References
- 6. CYCLIC VOLTAMETRIC STUDIES
- 6.1.Introduction
- 6.2.Experimental procedure
- 6.3.Pretreatment of platinum electrode Cyclic voltammogram studies of PPy (Ho04) 2
- Fig.6.1.Schematic of the experimental arrangementfor cyclic voltammetry.
- 6.4.films using an aqueous solution of ammonium molybdate and H SO as the electrolyte Cyclic voltammogram studies of PPy (No0) 2
- Fig.6.2.Cyclic voltammogram of thin film of PPy (Mo04) 2- for different scanning rates.
- 6.5.films using an aqueous solution of molybdic acid as the electrolyte Cyclic voltammogram studies of PPy (PO) 3
- Fig.6.3.Cyclic voltammogram of the thick film of PPy (Mo04) 2- .
- 6.6.films using an aqueous solution A
- Fig. 6.4.Cyclic voltammogram of thin films of PPy (Mo04) 2- for different scanning rates.
- Fig.6.5.Cyclic voltammogram of PPy (PO4) 3 for different scanning rates.
- CONCLUSION
- References
- 7. ULTRASONIC STUDIES IN POLYPYRROLE SAMPLES
- 7.1.Introduction
- 7.2.Ultrasonic studies in polymers
- 7.3.Ultrasonic velocity measurement methods
- 7.3.1. Pulse-echo-overlap (PEO) method
- 7.3.2. Pulse-echo-overlap system
- Fig.7.1. Block diagram of the equipment for echooverlap measurements with rf pulses.
- Fig.7.2.Overlapped broad band echoes from thepulse-echo-overlap system.
- 7.4.Word done in the present study
- 7.5.Experimental details
- 7.6.Results and discussion
- Table 7; l Ultrasonic velocity and attenuation of ultrasonic waves in polypyrrole solution ofdifferent concentration and teqeratures
- Table 7.2 Compressibility of polypyrrole solution ofdifferent temperature and concentration
- Fig.7.3. Variation of ultrasonic velocity with temperature.
- Fig.7.4 variation of compressibility with temperature
- Fig.7.5.Variation of ultrasonic velocity with concentration.
- Fig.7.6.Variation o f compressibility with concentration.
- Fig.7.7.Variation of attenuation with concentration
- Table 7.3 Elastic constants for chemical prepared polypyrrole pellets
- CONCLUSION
- References
- 8. THERMOGRAVIMETRY, DIFFERENTIAL THERMAL ANALYSIS AND X-RAY STUDIES IN SOME POLYPYRROLE SAMPLES
- 8.1.Introduction
- 8.2.Experimental
- Fig. 8.1.TGA of conducting polypyrrole film preparedby electrochemical method.
- Fig.8.2.DTA of conducting polypyrrole film preparedby electrochemical method.
- Fig.8.3.TGA of polypyrrole film prepared bychemical method.
- Fig.8.4.DTA of polypyrrole film prepared bychemical method.
- Fig.8.5 TGA of polypyrrole powder prepared by chemical method.
- Fig.8.6.DTA of polypyrrole powder prepared by chemical method.
- Fig.8.7. X-ray diffraction pattern of the polypyrrole film prepared by electrochemical methods.
- Fig.8.8. x-ray diffraction pattern of the polypyrrole film prepared by chemical methods.
- Fig.8.9. X-ray diffraction pattern of the polypyrrole powder prepared by chemical methods.
- 8.3.Results and discussion
- CONCLUSION
- References