Verfügbarkeit: Photocatalysis

Photocatalysis: science and technology

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Format:	Buch
Sprache:	English
Veröffentlicht:	Berlin [u.a.] Springer 2002 Tokyo Kodansha
Schriftenreihe:	Biological and medical physics series Physics and astronomy online library
Schlagworte:	Catálise Fotoquímica Photocatalyse Photocatalysis Fotokatalyse
Online-Zugang:	Inhaltsverzeichnis
Beschreibung:	XVI, 356 S. Ill., graph. Darst.
ISBN:	3540434739 4062106159

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Datensatz im Suchindex

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adam_text	Contents List of Contributors .................................................................................... v Preface ......................................................................................................... vii 1 Introduction ....................................................................................... 1 1.1 Background ................................................................................ 1 1.2 Aim and Outline of This Volume ............................................. 2 1.3 Summary .................................................................................... 4 1.4 Future Perspectives .................................................................... 4 References ............................................................................................ 5 I Fundamental Aspects of Photocatalysts Photoelectrochemical Processes of Semiconductors 9 2.1 Semiconductor Electrodes for Solar Energy Conversion ........ 11 2.2 Reduction of CO2 at Illuminated Semiconductor Electrodes ·· IS 2.3 Photocatalysis ............................................................................ 18 2.3.1 General Remarks ........................................................... 18 2.3.2 Mechanistic Studies ...................................................... 19 2.3.3 Low Intensity Illumination ........................................... 22 2.3.4 Applications ................................................................... 24 References ............................................................................................ 26 Design, Preparation and Characterization of Highly Active Metal Oxide Photocatalysts 29 3.1 Introduction ................................................................................ 29 3.2 Photocatalytic Activity .............................................................. 29 3.2.1 Effect of Surface Area on Photocatalytic Activity ...... 30 3.2.2 Effect of Electron-hole Recombination on Photocatalytic Activity .......................................................................... 3.2.3 Design of Photocatalysts of High Activity 3.3 Preparation of Titanium(IV) Oxide Powders 3.3.1 Sulfate Method .............................................................. 3.3.2 Chloride Method (Vapor Method) 3.3.3 Alkoxide Method ........................................................... ι Contents 3.3.4 Specific Methods ........................................................... 34 3.3.5 Activation of TiO2 Photocatalysts ................................ 36 3.4 Preparation of Other Photocatalysts ......................................... 38 3.5 Characterization of TiO2 Photocatalysts of Both High Crystallinity and Large Surface Area ............................................................. 38 3.5.1 Photocatalytic Activity of HyCOM TiO2 in Aqueous Suspension Systems ...................................................... 38 3.5.2 Correlation Between Physical Properties and Photocatalytic Activity of HyCOM TiO2 39 3.5.3 Novel Hypothesis for Activity of Photocatalyst .......... 43 3.6 Preparation and Characterization of Photocatalytic Thin Films ................................................................................................... 44 3.6.1 Preparation of Photocatalytic TiO2 Thin Films ........... 44 3.6.2 Characterization of Photocatalytic Thin Films Prepared from HyCOM TiO2 Powders ........................................ 45 3.7 Summary .................................................................................... 47 References ............................................................................................ 47 4 Photoelectrochemistry at Semiconductor/Liquid Interfaces ···■ 51 4.1 Introduction ................................................................................ 51 4.2 Basic Properties of Semiconductor/Liquid Interface ............... 52 4.2.1 Band Bending ................................................................ 52 4.2.2 Barrier Height and Flat Band Potential ........................ 54 4.2.3 Electron Transfer and Corrosion Reactions ................. 57 4.3 Photoelectrochemistry at Atomically Well-defined Surfaces ■ 59 4.3.1 Atomically Flat H-terminated Si Surfaces 59 4.3.2 Selective Exposition of ( 100) Face on n-TiO2 (Rutile) by Photoetching .................................................................. 62 4.4 Photoelectrochemistry at Metal Dot-coated Semiconductors ·· 64 4.4.1 Ideal Semiconductor Electrodes ................................... 64 4.4.2 Metal-loaded TiO2 Electrodes ....................................... 66 References ............................................................................................ 67 5 Photoelectrochemical Reactions at Semiconductor Microparticle ■ 69 5.1 Introduction ................................................................................ 69 5.2 Energy Structure of Semiconductor Microparticle .................. 69 5.2.1 Depletion Layer ............................................................. 69 5.2.2 Electric Heterogeneity of Surface ................................ 71 5.2.3 Size Quantization Effect ............................................... 72 5.3 Kinetics at Semiconductor Microparticle .................................... 72 5.3.1 Recombination Model ................................................... 73 5.3.2 2D Ladder Model .......................................................... 74 5.3.3 Effect of Size ................................................................. 76 5.4 Observation of Primary Reaction Intermediates ......................... 77 5.4.1 ESR Analysis for Irradiated TiO2 Particles .................. 78 5.4.2 Direct Observation of Intermediate Radicals ............... 81 5.4.3 Chemiluminescent Probe for Active Oxygens ............. 83 References ............................................................................. .............. g5 Contents xi 6 New Approaches in Solution-phase Processing of Semiconductor Thin Films .......................................................................................... 87 6.1 Introduction ................................................................................ 87 6.2 Previous Methods for Solution-phase Deposition of Semiconductor Thin Films .................................................................................. 89 6.2.1 Chemical Bath Deposition of Metal Sulfide Thin Films ............................................................................................ 89 6.2.2 Electrodeposition of Metal Sulfide Thin Films ........... 90 6.2.3 Chemical and Electrochemical Deposition of Metal Oxide Thin Films ...................................................................... 92 6.3 Electrochemically Induced Chemical Deposition (EICD) of CdS Thin Films .................................................................................. 93 6.3.1 Idea ................................................................................. 93 6.3.2 Morphological and Structural Analysis ........................ 94 6.3.3 Growth Kinetics and Mechanism of EICD Process ..... 95 6.3.4 Modification of EICD Process ...................................... 97 6.4 True Electrodeposition of Metal Sulfide Thin Films by Reduction of Thiocyanato Complexes ........................................................ 97 6.4.1 Idea ................................................................................. 97 6.4.2 Thermodynamic Consideration ..................................... 98 6.4.3 Electrochemical Layer-by-layer Growth of CdS Thin Films ...................................................................... 98 6.4.4 Electrodeposition of Other Metal Sulfides ................... 100 6.5 Electrochemical Self-assembly of ZnO/Dye Hybrid Thin Films .................................................................................. 100 6.5.1 Idea ................................................................................. 100 6.5.2 Electrochemical Self-assembly of ZnO/Dye Hybrid Structure ......................................................................... 102 6.5.3 Mechanism of Electrochemical Self-assembly ............ 104 6.6 Summary .................................................................................... 104 References ............................................................................................ 105 II Application to Environmental Cleaning 7 Self-cleaning Properties of TiCVcoated Substrates 109 7.1 Introduction ................................................................................ 109 7.2 Photocatalytic Decomposition .................................................. 110 7.2.1 Air Purifying Effect ...................................................... 110 7.2.2 Sterilization Effect ........................................................ Ill 7.2.3 Anti-fouling Effect ........................................................ 113 7.2.4 Photo-induced High Amphiphilicity ............................ 114 7.3 Conclusions ................................................................................ 120 References ............................................................................................ 121 8 Cleaning Atmospheric Environment ............................................. 123 8.1 Introduction ................................................................................ 123 8.2 Photocatalytic Activities of TiO2 .............................................. 124 xii Contents 8.2.1 Oxidation of Air Pollutants by Photogenerated Active Oxygen Species ............................................................. 124 8.2.2 Photocatalytic Reactions of Volatile Hydrocarbons ·■·■ 125 8.2.3 Photocatalytic Reactions of Halogenated Hydrocarbons ............................................................................................ 136 8.2.4 Nitrogen Oxides (NO,) .................................................. 143 8.3 Development of Air Purifying Materials Based on Photocatalyst .............................................................................. 147 8.3.1 Immobilization of Powder Photocatalysts ................... 147 8.3.2 Preparation of Air-purifying Materials ........................ 148 8.3.3 Performance Characteristics of Air-purifying Materials ........................................................................ 149 8.4 Application of Photocatalysis to Cleaning of Atmospheric Environment ............................................................................... 151 8.4.1 Passive Purification of Polluted Air 151 8.4.2 Active Air Purification of Closed Space ...................... 153 8.5 Summary .................................................................................... 154 References ............................................................................................ 155 9 Water Purification — Degradation of Aqueous Pollutant and Application to Water Treatment .................................................... 157 9.1 Introduction ............................................................................... 157 9.2 Photocatalytic Characteristics of Titanium Dioxide ................ 157 9.3 Photocatalytic Degradation of Pollutant 160 9.3.1 Volatile Organohalide Compound 160 9.3.2 Pesticides ....................................................................... 162 9.3.3 Other Organic Compounds ........................................... 164 9.3.4 Environmental Hormones (Endocrine Disruptors) ...... 165 9.4 Enhancement of Degradation Rate ........................................... 166 9.4.1 Pt-loading ....................................................................... 166 9.4.2 Addition of H2O2 ........................................................... 167 9.4.3 Ozone ............................................................................. 169 9.4.4 Increase in Adsorption .................................................. 169 9.5 Solar System for Water Treatment ........................................... 171 9.6 Immobilization of TiO2 and Instrumentation ........................... 171 9.7 Conclusion and Outlook ............................................................ 172 References ............................................................................................ 172 10 Second-generation TiO2 Photocatalysts Able to Initiate Reactions Under Visible Light Irradiation ..................................................... 175 10.1 Introduction ................................................................................ 175 10.2 Experimental Section ................................................................. 175 10.3 Results and Discussion .............................................................. 176 10.4 Conclusion ................................................................................. 182 References ............................................................................................ 182 Contents III Application to Photoenergy Conversion 11 Photocatalytic Organic Syntheses Using Semiconductor Particles .............................................................................................. 185 11.1 Introduction ................................................................................ 185 11.2 Principle of Photocatalysis by Semiconductor Particles .......... 186 11.3 Photocatalytic Reactions by Semiconductor Suspension ........ 187 11.4 Redox Combined Photocatalytic Processes for Nitrogen-containing Substrates ................................................................................... 189 11.5 Further Development to Stereoselective Organic Synthesis of Nitrogen-containing Compounds .............................................. 191 11.6 Introduction of Oxygen Atoms into Organic Compounds ....... 194 11.6.1 Stereospecific Epoxidation of 2-hexene on Photoirradiated TiO2 Powders Using Molecular Oxygen as Oxidant — 195 11.6.2 Selective Oxidation of Naphthalene by Molecular Oxygen and Water Using ТЮг Photocatalysts .......................... 196 11.6.3 Photocatalytic Oxygénation: Summary ........................ 198 11.7 Concluding Remarks ................................................................. 199 References ............................................................................................ 199 12 Sonophotocatalysis — Joint System of Sonochemical and Photocatalytic Reactions ................................................................. 203 12.1 Introduction — What is Sonophotocatalysis? ............................ 203 12.2 Utilization of Sonophotocatalytic Reaction ............................. 204 12.2.1 Sonophotocatalysis of Water ........................................ 204 12.2.2 Sonophotocatalysis of Artificial Seawater ................... 216 12.2.3 Sonophotocatalyses of Organic Compounds ................ 219 12.3 Conclusion and Future Scopes .................................................. 220 References ............................................................................................ 221 13 Gas-phase Water Photolysis by NaOH-coated Photocatalysts 223 13.1 Introduction ................................................................................ 223 13.2 Water Photolysis by Pt/TiO2 ..................................................... 224 13.3 Water Photolysis by Metallized Semiconductor Powders ....... 226 13.3.1 Gas-phase Water Photolysis by NaOH-coating 226 13.3.2 Factors Influencing Yield of Water Photolysis 229 13.4 Concluding Remarks ................................................................. 233 References ............................................................................................ 234 14 Water Photolysis by TiO2 Particles—Significant Effect of Na2CO3 Addition on Water Splitting 235 14.1 Introduction ................................................................................ 235 14.2 Significant Effect of Carbonate Salt Addition on Water Splitting from Pt/TiO2 Water Suspension ................................................ 236 14.3 Role of Carbonate Salts on Water Splitting and Reaction Mechanism ................................................................................. 240 xiv Contents 14.4 Effective Screening of Active Photocatalysts for Water Splitting Using Na2CO} Addition Method ............................................... 242 14.5 Solar Hydrogen Production Using NajCOj Addition Method 246 14.6 Conclusion ................................................................................. 248 References ............................................................................................ 248 15 Water Photolysis by Titanates with Tunnel Structures 249 15.1 Water Photolysis by RuOj/BaTuO, with Pentagonal Prism Tunnel Structure ........................................................................ 250 15.2 Water Photolysis by RuCb/^TUO, , with Rectangular Tunnel Structure ..................................................................................... 257 References ............................................................................................ 260 16 Water Photolysis by Layered Compounds ................................... 261 16.1 Introduction ................................................................................ 261 16.2 Layered Oxides of Transition Metals ....................................... 261 16.3 K4NDA7 .................................................................................... 263 16.3.1 Structure and Physico-chemical Properties .................. 263 16.3.2 Photocatalytic Overall Water Splitting 265 16.3.3 Structure of Ni-loaded K4Nb6O17 and Reaction Mechanism ..................................................................... 267 16.4 Perovskite-related Layered Oxides ........................................... 268 16.5 Summary .................................................................................... 276 References ............................................................................................ 276 17 Splitting of Water by Combining Two Photocatalytic Reactions via Quinone Redox Couple Dissolved in Oil Phase: Artificial Photosynthesis ................................................................................... 279 17.1 Introduction ................................................................................ 279 17.2 Strategy for Water Splitting by Mimicking Photosynthesis 280 17.3 Photocatalytic Hydrogen and Oxygen Evolution in Separate Systems ...................................................................................... 281 17.3.1 Photooxidation of Water Using ТІО2 Particles 282 17.3.2 Photoreduction of Water Using Pt-loaded TiO2 Particles .......................................................................... 285 17.4 Approaches to Electrochemical and Chemical Combinations of Two Photocatalytic Reactions ................................................... 286 17.5 Splitting of Water by a Combination of Two Photocatalytic Reactions via DDQ/DDHQ ....................................................... 289 17.6 Conclusions ................................................................................ 291 References ............................................................................................ 291 18 Sensitization by Metal Complexes Towards Future Artificial Photosynthesis ................................................................................... 293 18.1 Introduction ................................................................................ 293 18.2 Photoinduced Hydrogen Evolution in Homogeneous Four-component Systems .......................................................... 294 Contents xv 18.2.1 Photoinduced Hydrogen Evolution with Porphyrin Metal Complexes and Hydrogenase ........................................ 294 18.2.2 Photoinduced Hydrogen Evolution Using Cytochrome Cj as Electron Carrier .................................................... 296 18.2.3 Photoinduced Hydrogen Evolution Using Chemically-modified Chlorophyll ................................ 298 18.3 Photoinduced Hydrogen Evolution with Viologen-linked orphyrin Metal Complexes ........................................................ 299 18.3.1 Photoinduced Hydrogen Evolution with Water-soluble Viologen-linked Cationic Porphyrin Metal Complexes and Hydrogenase ........................................................... 300 18.3.2 Photoinduced Hydrogen Evolution with Water-soluble Viologen-linked Anionie Porphyrin and Hydrogenase ........................................................................................ 302 18.4 Other Systems for Hydrogen Evolution Using Natural Photosensitizers ......................................................................... 303 18.5 Conclusion ................................................................................. 306 References ............................................................................................ 306 19 Catalyses and Sensitization for Water Reaction Towards Future Artificial Photosynthesis 309 19.1 Introduction ................................................................................ 309 19.2 Design of Artificial Photosynthesis 309 19.2.1 Photosynthesis and Energy Cycle on Earth ................. 309 19.2.2 Artificial Photosynthesis 311 19.3 Molecular Catalysts for Water Reactions and CO2 Reduction 312 19.3.1 Catalysis in Water Oxidation 312 19.3.2 Catalysis in Proton Reduction ...................................... 316 19.3.3 Catalysis in Carbon Dioxide Reduction ....................... 316 19.4 Photoexcited State Electron Transfer in Heterogeneous Phases .................................................................................................... 317 19.5 Sensitization of TiO2 Powders and Films in Water ................. 320 19.6 Conclusion and Future Prospects .............................................. 322 References ............................................................................................ 323 20 Photoelectric TiO2 Solar Cells 325 20.1 Introduction ................................................................................ 325 20.2 Dye-sensitization of Semiconductors ....................................... 325 20.2.1 History ........................................................................... 325 20.2.2 Innovative Dye-sensitized Solar Cells ........................ 327 20.2.3 Fabrication of Dye-sensitized TiO2 Solar Cells 328 20.2.4 Characterization of Innovative Dye-sensitized TiO2 Solar Cells ............................................................. 329 20.3 Electron-transfer Sensitization on TiO2 .................................... 330 20.3.1 Bonding Structure of Dye on TiO2 Influencing rjt, 331 20.3.2 Dynamics in Electron Transfer from Photoexcited Dye 2 to TiO2 ............................................................................ 331 Contents 20.3.3 Electron Transfer Between Oxidized Dye 2 and Г/Ь Electrolyte ...................................................................... 332 20.4 Electron Transport in Porous TiO2 Electrodes 333 20.4.1 Electron Transport Models for High ηα ....................... 334 20.4.2 Time-course Analysis .................................................... 335 20.4.3 Frequency Analysis ....................................................... 335 20.4.4 Effect of TiOj Films on Performance of Dye-sensitized Solar Cells ..................................................................... 337 20.5 Sensitization Dyes ..................................................................... 337 20.5.1 Ruthenium Polypyridine Complexes ............................ 337 20.5.2 Other Metal Complexes ................................................ 339 20.5.3 Organic Dyes ................................................................. 340 20.5.4 Natural Dyes .................................................................. 342 20.6 Recent Research Progress in Dye-sensitized Solar Cells ........ 343 20.7 Future Work on Dye-sensitized Solar Cells ............................. 344 20.8 Concluding Remarks ................................................................. 345 References ............................................................................................ 346 Index ..................................................................................................... 349
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title	Photocatalysis science and technology
title_auth	Photocatalysis science and technology
title_exact_search	Photocatalysis science and technology
title_full	Photocatalysis science and technology Masao Kaneko ... (eds.)
title_fullStr	Photocatalysis science and technology Masao Kaneko ... (eds.)
title_full_unstemmed	Photocatalysis science and technology Masao Kaneko ... (eds.)
title_short	Photocatalysis
title_sort	photocatalysis science and technology
title_sub	science and technology
topic	Catálise larpcal Fotoquímica larpcal Photocatalyse ram Photocatalysis Fotokatalyse (DE-588)4193873-2 gnd
topic_facet	Catálise Fotoquímica Photocatalyse Photocatalysis Fotokatalyse
url	http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=009906281&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA
work_keys_str_mv	AT kanekomasao photocatalysisscienceandtechnology

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