Molecular Water Oxidation Catalysis.

Photocatalytic water splitting is a promising strategy for capturing energy from the sun by coupling light harvesting and the oxidation of water, in order to create clean hydrogen fuel. Thus a deep knowledge of the water oxidation catalysis field is essential to be able to come up with useful energy...

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Bibliographic Details
Main Author: Llobet, Antoni
Format: eBook
Language:English
Published: Hoboken : Wiley, 2014.
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Online Access:Click for online access

MARC

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245 1 0 |a Molecular Water Oxidation Catalysis. 
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505 0 |a Cover -- Title Page -- Copyright -- Contents -- List of Contributors -- Preface -- Chapter 1 Structural Studies of Oxomanganese Complexes for Water Oxidation Catalysis -- 1.1 Introduction -- 1.2 Structural Studies of the OEC -- 1.3 The Dark-Stable State of the OEC -- 1.4 Biomimetic Oxomanganese Complexes -- 1.5 Base-Assisted O-O Bond Formation -- 1.6 Biomimetic Mn Catalysts for Artificial Photosynthesis -- 1.7 Conclusion -- Acknowledgments -- References -- Chapter 2 O-O Bond Formation by a Heme Protein: The Unexpected Efficiency of Chlorite Dismutase -- 2.1 Introduction -- 2.2 Origins of O2-Evolving Chlorite Dismutases (Clds) -- 2.3 Major Structural Features of the Proteins and their Active Sites -- 2.4 Efficiency, Specificity, and Stability -- 2.5 Mechanistic Insights from Surrogate Reactions with Peracids and Peroxide -- 2.6 Possible Mechanisms -- 2.7 Conclusion -- Acknowledgements -- References -- Chapter 3 Ru-Based Water Oxidation Catalysts -- 3.1 Introduction -- 3.2 Proton-Coupled Electron Transfer (PCET) and Water Oxidation Thermodynamics -- 3.3 O-O Bond Formation Mechanisms -- 3.4 Polynuclear Ru Water Oxidation Catalysts -- 3.5 Mononuclear Ru WOCs -- 3.6 Anchored Molecular Ru WOCs -- 3.7 Light-Induced Ru WOCs -- 3.8 Conclusion -- Acknowledgments -- References -- Chapter 4 Towards the Visible Light-Driven Water Splitting Device: Ruthenium Water Oxidation Catalysts with Carboxylate-Containing Ligands -- 4.1 Introduction -- 4.2 Binuclear Ru Complexes -- 4.3 Mononuclear Ru Complexes -- 4.3.1 Ru-O2N-N3 Analogs -- 4.3.2 Ru-O2N2-N2 Analogs -- 4.4 Homogeneous Light-Driven Water Oxidation -- 4.4.1 The Three-Component System -- 4.4.2 The Supramolecular Assembly Approach -- 4.5 Water Oxidation Device -- 4.5.1 Electrochemical Water Oxidation Anode -- 4.5.2 Photo-Anode for Water Oxidation -- 4.6 Conclusion -- References. 
505 8 |a 8.2 Fe-Tetrasulfophthalocyanine -- 8.3 Fe-TAML -- 8.4 Fe-mcp -- 8.5 Fe2O3 as a Microheterogeneous Catalyst -- 8.6 Conclusion -- References -- Chapter 9 Water Oxidation by Co-Based Oxides with Molecular Properties -- 9.1 Introduction -- 9.2 CoCat Formation -- 9.3 Structure and Structure-Function Relations -- 9.4 Functional Characterization -- 9.5 Directly Light-Driven Water Oxidation -- References -- Chapter 10 Developing Molecular Copper Complexes for Water Oxidation -- 10.1 Introduction -- 10.2 A Biomimetic Approach -- 10.2.1 Thermochemistry: Developing Oxidant/Base Combinations as PCET Reagents -- 10.2.2 Copper Complexes with Alkylamine Ligands -- 10.2.3 Copper Complexes with Anionic Ligands -- 10.2.4 Lessons Learned: Thermochemical Insights and Oxidant/Base Compatibility -- 10.3 An Aqueous System: Electrocatalysis with (bpy)Cu(II) Complexes -- 10.3.1 System Selection: bpy + Cu -- 10.3.2 Observing Electrocatalysis -- 10.3.3 Catalyst Turnover Number and Turnover Frequency -- 10.3.4 Catalyst Speciation: Monomer, Dimer, or Nanoparticles? -- 10.4 Conclusion -- Acknowledgement -- References -- Chapter 11 Polyoxometalate Water Oxidation Catalytic Systems -- 11.1 Introduction -- 11.2 Recent POM WOCs -- 11.3 Assessing POM WOC Reactivity -- 11.4 The Ru(oxbpy)32+/S2O82- System -- 11.5 Ru(bpy)33+ as an Oxidant for POM WOCs -- 11.6 Additional Aspects of WOC System Stability -- 11.7 Techniques for Assessing POM WOC Stability -- 11.8 Conclusion -- Acknowledgments -- References -- Chapter 12 Quantum Chemical Characterization of Water Oxidation Catalysts -- 12.1 Introduction -- 12.2 Computational Details -- 12.2.1 Density Functional Theory Calculations -- 12.2.2 Multiconfigurational Calculations -- 12.3 Methodology -- 12.3.1 Solvation and Standard Reduction Potentials -- 12.3.2 Multideterminantal State Energies. 
505 8 |a 12.4 Water Oxidation Catalysts -- 12.4.1 Ruthenium-Based Catalysts -- 12.4.2 Cobalt-Based Catalysts -- 12.4.3 Iron-Based Catalysts -- 12.5 Conclusion -- References -- Index -- Supplemental Images. 
520 |a Photocatalytic water splitting is a promising strategy for capturing energy from the sun by coupling light harvesting and the oxidation of water, in order to create clean hydrogen fuel. Thus a deep knowledge of the water oxidation catalysis field is essential to be able to come up with useful energy conversion devices based on sunlight and water splitting. Molecular Water Oxidation Catalysis: A Key Topic for New Sustainable Energy Conversion Schemes presents a comprehensive and state-of-the-art overview of water oxidation catalysis in homogeneous phase, describing in detail the most important catalysts discovered today based on first and second row transition metals. A strong emphasis is placed on the description of their performance, as well as how they work from a mechanistic perspective. In addition, a theoretical description of some of the most relevant catalysts based on DFT are presented, as well as a description of related natural systems, such as the oxygen evolving system of photosystem II and the heme chlorite-dismutase. This book is a valuable resource for researchers working on water oxidation catalysis, solar energy conversion and artificial photosynthesis, as well as for chemists and materials scientists with a broad interest in new sustainable energy conversion schemes. 
650 0 |a Electric power production from chemical action. 
650 0 |a Energy harvesting. 
650 0 |a Renewable energy sources. 
650 0 |a Water  |x Purification  |x Oxidation  |x By-products. 
650 7 |a Electric power production from chemical action  |2 fast 
650 7 |a Energy harvesting  |2 fast 
650 7 |a Renewable energy sources  |2 fast 
758 |i has work:  |a Molecular Water Oxidation Catalysis (Text)  |1 https://id.oclc.org/worldcat/entity/E39PCYh7dhmQqVHwP9YbjPMfhd  |4 https://id.oclc.org/worldcat/ontology/hasWork 
776 0 8 |i Print version:  |a Llobet, Antoni.  |t Molecular Water Oxidation Catalysis.  |d Hoboken : Wiley, ©2014  |z 9781118413371 
856 4 0 |u https://ebookcentral.proquest.com/lib/holycrosscollege-ebooks/detail.action?docID=1676376  |y Click for online access 
880 8 |6 505-00/(S  |a Chapter 5 Water Oxidation by Ruthenium Catalysts with Non-Innocent Ligands -- 5.1 Introduction -- 5.2 Water Oxidation Catalyzed by Dinuclear Ruthenium Complexes with NILs -- 5.3 Water Oxidation by Intramolecular O-O Coupling with [Ru II2(μ-Cl)(bpy)2(btpyan)]3+ -- 5.4 Mononuclear Ru-Aqua Complexes with a Dioxolene Ligand -- 5.4.1 Structural Characterization -- 5.4.2 Theoretical and Electrochemical Characterization -- 5.5 Mechanistic Investigation of Water Oxidation by Dinuclear Ru Complexes with NILs: Characterization of Key Intermediates -- References -- Chapter 6 Recent Advances in the Field of Iridium-Catalyzed Molecular Water Oxidation -- 6.1 Introduction -- 6.2 Bernhard 2008 [11] -- 6.3 Crabtree 2009 [12] -- 6.4 Crabtree 2010 [13] -- 6.5 Macchioni 2010 [14] -- 6.6 Albrecht/Bernhard 2010 [15] -- 6.7 Hetterscheid/Reek 2011 [16,17] -- 6.8 Crabtree 2011 [18] -- 6.9 Crabtree 2011 [19] -- 6.10 Lin 2011 [20] -- 6.11 Macchioni 2011 [21] -- 6.12 Grotjahn 2011 [22] -- 6.13 Fukuzumi 2011 [23] -- 6.14 Lin 2012 [24] -- 6.15 Crabtree 2012 [25-27] -- 6.16 Albrecht/Bernhard 2012 [28] -- 6.17 Crabtree 2012 [29] -- 6.18 Beller 2012 [30] -- 6.19 Lin 2012 [31] -- 6.20 Lloblet and Macchioni 2012 [33] -- 6.21 Analysis -- References -- Chapter 7 Complexes of First Row d-Block Metals: Manganese -- 7.1 Background -- 7.2 Oxidation States of Manganese in an Aqueous Environment -- 7.3 Dinuclear Manganese Complexes: Syntheses and Structures -- 7.4 Redox and Acid-Base Chemistry of Mn2- -WDL Systems -- 7.5 Mn2 Systems: Oxygen Evolution (but not Water Oxidation) Catalysis -- 7.6 Mn2 Complexes/the OEC/Ru2 Catalysts: A Comparison -- 7.7 Heterogeneous Water Oxidation Catalysis by Mn>2 Systems -- 7.8 Conclusion -- Acknowledgements -- References -- Chapter 8 Molecular Water Oxidation Catalysts from Iron -- 8.1 Introduction. 
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