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Full Screen- TITLE
- DEDICATION
- CERTIFICATE
- DECLARATION
- ACKNOWLEDGEMENT
- CONTENTS
- 1. Introduction and Objectives
- 1. General
- 1.1 Advanced Oxidation Process (AOP)
- Fig.1.2. A schematic representation of the cavitation process
- Fig.1.3. Three reaction zones of sonochemical reactions
- 1.2 The hydroxyl radical (OH): Properties and general reactions
- 1.3 OBJECTIVES
- 2. Experimental
- 2.1. Materials
- 2.2. Synthesis of ferric perchlorate
- 2.3. Photoirradiation
- 2.4. Radiation Chemical techniques
- Fig.2.1. Schematic representation of pulse radiolysis set-up
- 2.5. Sonochemical method: Sonolysis and Ozonolysis
- Fig.2.2. Schematic representation of sonochemical experimental set-up
- 2.6. Product Analysis
- Fig.2.3. Ion source design in API-Electrospray
- Fig.2.4. Ion generation in API-Electrospray
- 3. Photoproduction Of Hydroxyl Radicals From Fe (Ill) -Hydroxy Complex: A Quantitative Assessment And Determination Of Its Reaction Rate Constants With Some Substituted Benzenes And Biomolecules
- 3.1 Photolysis of ferric perchlorate
- 3.2. A comparative study with radiation chemical experiments
- 3.3. Determination of rate constants using competition kinetics
- 4. Oxidative Degradation Of Triazine Derivatives In Aqueous Medium: A Radiation And PhotochemicaI Study
- 4.1. Pulse Radiolysis Studies
- 4.2. Degradation of triazine derivatives using steady state radiolysis and photochemical method
- 5. Sonochemical Degradation Of Azobenzene And Its Derivatives
- 5.1 Sonochemical bleaching and mineralization
- 5.2 Rate enhancement in the bleaching of methyl orange via Fenton reaction
- 5.3. Synergistic effects of sonolysis combined with ozonolysis for theoxidation of azobenzene and methyl orange
- Fig.5.11. Initiation, promotion and inhibition of the decomposition of O3 (aq) under ultrasonic irradiation.
- 5.4. The role of H2O and O2 in the sonolysis of BQ
- Summary and Conclusions
- Reference
- List of Publications