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Tabla de Contenidos:
  • PHOTOCATALYSIS ON TITANIA-COATED ELECTRODE-LESS DISCHARGE LAMPS; PHOTOCATALYSIS ONTITANIA-COATEDELECTRODE-LESS DISCHARGELAMPS; CONTENTS; PREFACE; INTRODUCTION; UV/VIS DISCHARGES IN ELECTRODELESS LAMPS; 2.1. THEORY OF THE DISCHARGE; 2.2. CONSTRUCTION OF ELECTRODELESS LAMPS; 2.3. SPECTRAL CHARACTERISTICS OF ELECTRODELESS LAMPS; 2.4. PERFORMANCE OF ELECTRODELESS LAMPS; THIN TITANIA FILMS ON ELECTRODELESS LAMPS; 3.1. PREPARATION OF THE THIN TITANIA FILMS; 3.2. TRANSITION METAL DOPED THIN TITANIA FILMS; 3.3. CHARACTERIZATION OF THIN TITANIA FILMS; 3.3.1. X-ray Diffraction (XRD).
  • 3.3.2. Raman Spectroscopy3.3.3. X-ray Photoelectron Spectroscopy (XPS); 3.3.4. Scanning Electron Microscopy (SEM); 3.3.5. Atomic Force Microscopy (AFM); 3.3.6. UV/Vis Absorption Spectroscopy; 3.4. PHOTOCATALYTIC ACTIVITY OF THIN TITANIA FILMS; INTERACTIONS OF MW RADIATION WITH THE UV/VIS-ILLUMINATED TITANIA; NOVEL MICROWAVE PHOTOCATALYTIC REACTORS; 5.1. BATCH EXPERIMENTAL SET-UP; 5.2. CONTINUOUS-FLOW EXPERIMENTAL SET-UP; MICROWAVE PHOTOCATALYSIS WITH TITANIA-COATED ELECTRODELESS LAMPS; 6.1. EFFECT OF ELECTRODELESS LAMPS; 6.1.1. Effect of the Number of Coating Cycles (in Batch Type).
  • 6.1.2. Effect of Light Intensity (in Batch Type)6.1.3. Effect of Number of the Coated EDLs (in Continuous-flow type); 6.1.4. Effect of Pure and V-, Zr-, and Ag-doped Titania (in Batch Type); 6.2. EFFECT OF REACTION CONDITIONS; 6.2.1. Effect of Initial pH (in Batch Type); 6.2.2. Effect of Air Bubbling (in Batch and Continuous-flow Types); 6.2.3. Effect of H2O2 Dosages (in Batch Type); 6.2.4. Effect of Flow Rate and Reaction Temperature (in Continuous-flow Type); CONCLUSION; ACKNOWLEDGMENT; REFERENCES; INDEX.