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Written by one of the top scientists in this field, this is a systematic overview of the fundamental concepts and powerful applications.
The author presents the central theories and mechanisms in electron transfer, followed by several systems in nature where this is important, while also covering modern green applications.
An invaluable resource for graduate students and researchers working in this field in academia and industry.
Auteur
Shunichi Fukuzumi, PhD, is a Distinguished Professor of Ewha Womans University, South Korea, Designated Professor of Meijo University, Japan, and Professor Emeritus of Osaka University, Japan and authored over 1000 scientific publications. He is the director of the SORST (Solution Oriented Research for Science and Technology) project, and is also the leader of a Global COE (Centers of Excellence) program.
Texte du rabat
Offers a clear understanding of the mechanisms and applications of electron transfer Written by one of the top scientists in the field, this comprehensive book presents the central theories and mechanisms in electron transfer and provides an overview of several systems in nature where electron transfer is important. It also covers modern green applications dealing with electron transfer. Beginning with an introduction to the subject, Electron Transfer: Mechanisms and Applications continues with a chapter covering the Marcus Theory of electron transfer. Other chapters look at: photosynthetic reaction center models; electron donoracceptor dyads; supramolecular electron transfer; and the effects of metal ions on photoinduced electron transfer. Also discussed are topics such as photoredox catalysis; hydrogen storage; catalytic reduction of O2; catalytic oxidation of H2O; the production of hydrogen peroxide from water and oxygen as a solar fuel; and the production and usage of hydrogen peroxide as a solar fuel in seawater. The book finishes with a chapter on Photosystem II Mimic.
Contenu
Acknowledgments vii
1 Introduction 1
2 Marcus Theory of Electron Transfer 5
3 Photosynthetic Reaction Center Models 7
4 Electron DonorAcceptor Dyads 11
5 Supramolecular Electron Transfer 25
5.1 CationAnion Binding 25
5.2 -Complexes 35
5.3 Electron-Transfer Switching 46
5.4 Dendrimers 53
5.5 Supramolecular Solar Cells 55
6 Effects of Metal Ions on Photoinduced Electron Transfer 65
7 Photoredox Catalysis 69
7.1 Photocatalytic Oxygenation 69
7.2 Photocatalytic Oxibromination 77
7.3 CarbonCarbon Bond Formation 77
7.4 DNA Cleavage 81
7.5 Anti-Markovnikov Hydroetherification 81
7.6 Photocatalytic Cycloaddition 83
7.7 Photocatalytic Hydrotrifluoromethylation 85
7.8 Photocatalytic Hydrogen Evolution 86
8 Hydrogen Storage 93
8.1 Interconversion Between Hydrogen and Formic Acid 95
8.2 Interconversion Between Hydrogen and NADH 101
8.3 Hydrogen Evolution from Alcohols 104
8.4 Hydrogen Evolution from Paraformaldehyde 107
9 Metal Ion-Coupled Electron Transfer (MCET) 109
9.1 MCET of O2 109
9.2 Binding Modes of Metal Ions 114
9.3 Self-Organized MCET 124
9.4 Accelerating and Decelerating Effects of Metal Ions 132
9.5 Driving Force Dependence of MCET Rate Constants 137
9.6 MCET Coupled with Hydrogen Bonding 143
9.7 MCET Catalysis 148
9.7.1 Hydride Transfer vs. Cycloaddition 148
9.7.2 Suproxode Disumutase (SOD) Models 152
9.8 MCET of Metal-Oxo Complexes 157
9.9 PCET of Metal-Oxo Complexes 162
9.10 Unified Mechanism of MCET and PCET of Metal-Oxo Complexes 165
9.11 MCET of Metal-Peroxo Complexes 169
10 Catalytic Reduction of O2 173
11 Catalytic Oxidation of H2O 181
12 Production of Hydrogen Peroxide from Water and Oxygen as a Solar Fuel 187
13 Production and Usage of Hydrogen Peroxide as a Solar Fuel in Seawater 193
14 Photosystem II Mimic 197
15 Conclusion and Perspective 201
References 203
Index 225