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1.

図書

図書
edited by Richard C. Alkire ... [et al.]
出版情報: Weinheim : Wiley-VCH, c2010  xiii, 359 p. ; 25 cm
シリーズ名: Advances in electrochemical science and engineering / edited by Heinz Gerischer and Charles W. Tobias ; contributions from V. Brusic ... [et al.] ; v. 12
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Applications of Electrochemistry in the Fabrication and Characterization of Thin Film Solar Cells
Tailoring of Interfaces for the Photoelectrochemical Conversion of Solar Energy
Printable Materials and Technologies for the Dye-Sensitized Photovoltaic Cell with Flexible Substrates
Electrodeposited Porous ZnO Sensitized by Organic Dyes - Promising Materials for Dye-Sensitized Solar Cells with Potential Application in Large Scale
Thin Film Semiconductors Deposited in Nanometric Scales by Electrochemical and Wet Chemical Methods for Solar Cell Applications
Applications of Electrochemistry in the Fabrication and Characterization of Thin Film Solar Cells
Tailoring of Interfaces for the Photoelectrochemical Conversion of Solar Energy
Printable Materials and Technologies for the Dye-Sensitized Photovoltaic Cell with Flexible Substrates
2.

図書

図書
edited by D. Yogi Goswami, Frank Kreith
出版情報: Boca Raton : CRC Press, c2008  1 v. (various pagings) ; 27 cm
シリーズ名: Mechanical engineering series / series editor, Frank Kreith
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Introduction / D. Yogi Goswami1:
Energy Use by Sectors / 1.1:
Electrical Capacity Additions to 2030 / 1.2:
Present Status and Potential of Renewable Energy / 1.3:
Role of Energy Conservation / 1.4:
Energy Conversion Technologies / 1.5:
Energy Resources / Section I:
Fossil Fuels / 2:
Coal / Robert Reuther2.1:
Environmental Aspects / Richard Bajura2.2:
Oil / Philip C. Crouse2.3:
Natural Gas / 2.4:
Biomass Energy / Ralph P. Overend ; Lynn L. Wright3:
Biomass Feedstock Technologies / 3.1:
Biomass Conversion Technologies / 3.2:
Nuclear Resources / James S. Tulenko4:
The Nuclear Fuel Cycle / 4.1:
Processing of Nuclear Fuel / 4.2:
Solar Energy Resources / 5:
Solar Energy Availability / 5.1:
Earth-Sun Relationships / 5.2:
Solar Time / 5.3:
Solar Radiation on a Surface / 5.4:
Solar Radiation on a Horizontal Surface / 5.5:
Solar Radiation on a Tilted Surface / 5.6:
Solar Radiation Measurements / 5.7:
Solar Radiation Data / 5.8:
Wind Energy Resources / Dale E. Berg6:
Wind Origins / 6.1:
Wind Power / 6.2:
Wind Shear / 6.3:
Wind Energy Resource / 6.4:
Wind Characterization / 6.5:
Wind Energy Potential / 6.6:
Geothermal Energy / Joel L. Renner ; Marshall J. Reed7:
Heat Flow / 7.1:
Types of Geothermal Systems / 7.2:
Geothermal Energy Potential / 7.3:
Geothermal Applications / 7.4:
Environmental Constraints / 7.5:
Operating Conditions / 7.6:
Energy Conversion / Section II:
Steam Power Plant / John Kern8:
Rankine Cycle Analysis / 8.1:
Topping and Bottoming Cycles / 8.3:
Steam Boilers / 8.4:
Steam Turbines / 8.5:
Heat Exchangers, Pumps, and Other Cycle Components / 8.6:
Generators / 8.7:
Gas Turbines / Steven I. Freedman9:
Overview / 9.1:
History / 9.2:
Fuels and Firing / 9.3:
Efficiency / 9.4:
Gas Turbine Cycles / 9.5:
Cycle Configurations / 9.6:
Components Used in Complex Cycles / 9.7:
Upper Temperature Limit / 9.8:
Materials / 9.9:
Combustion / 9.10:
Mechanical Product Features / 9.11:
Internal Combustion Engines / David E. Klett ; Elsayed M. Afify10:
Engine Types and Basic Operation / 10.1:
Air Standard Power Cycles / 10.3:
Actual Cycles / 10.4:
Combustion in IC Engines / 10.5:
Exhaust Emissions / 10.6:
Fuels for SI and CI Engines / 10.7:
Intake Pressurization-Supercharging and Turbocharging / 10.8:
Hydraulic Turbines / Roger E.A. Arndt11:
General Description / 11.1:
Principles of Operation / 11.2:
Factors Involved in Selecting a Turbine / 11.3:
Performance Evaluation / 11.4:
Numerical Simulation / 11.5:
Field Tests / 11.6:
Stirling Engines / William B. Stine12:
Thermodynamic Implementation of the Stirling Cycle / 12.1:
Mechanical Implementation of the Stirling Cycle / 12.3:
Future of the Stirling Engine / 12.4:
Advanced Fossil Fuel Power Systems / Anthony F. Armor13:
Fuels for Electric Power Generation in the U.S / 13.1:
Coal as a Fuel for Electric Power (World Coal Institute 2000) / 13.3:
Clean Coal Technology Development / 13.4:
Pulverized-Coal Plants / 13.5:
Emissions Controls for Pulverized Coal Plants / 13.6:
Fluidized Bed Plants / 13.7:
Gasification Plants / 13.8:
Combustion Turbine Plants / 13.9:
Central Station Options for New Generation / 13.10:
Summary / 13.11:
Combined-Cycle Power Plants / Alex Lezuo14:
Combined-Cycle Concepts / 14.1:
Combined-Cycle Thermodynamics / 14.2:
Combined-Cycle Arrangements / 14.3:
Combined Heat and Power from Combined-Cycle Plants / 14.4:
Energy Storage Technologies / Rod Hammerschlag ; Christopher P. Schaber14.5:
Overview of Storage Technologies / 15.1:
Principal Forms of Stored Energy / 15.2:
Applications of Energy Storage / 15.3:
Specifying Energy Storage Devices / 15.4:
Specifying Fuels / 15.5:
Direct Electric Storage / 15.6:
Electrochemical Energy Storage / 15.7:
Mechanical Energy Storage / 15.8:
Direct Thermal Storage / 15.9:
Thermochemical Energy Storage / 15.10:
Nuclear Power Technologies / Edwin A. Harvego ; Kenneth D. Kok16:
Development of Current Power-Reactor Technologies / 16.1:
Next-Generation Technologies / 16.3:
Generation-IV Technologies / 16.4:
Fuel Cycle / 16.5:
Nuclear Waste / 16.6:
Nuclear Power Economics / 16.7:
Conclusions / 16.8:
Nuclear Fusion / Thomas E. Shannon17:
Fusion Fuel / 17.1:
Confinement Concepts / 17.3:
Tokamak Reactor Development / 17.4:
Fusion Energy Conversion and Transport / 17.5:
Solar Thermal Energy Conversion / 18:
Active Solar Heating Systems / T. Agami Reddy18.1:
Solar Heat for Industrial Processes / Riccardo Battisti ; Hans Schweiger ; Werner Weiss18.2:
Passive Solar Heating, Cooling, and Daylighting / Jeffrey H. Morehouse18.3:
Solar Cooling / Sanjay Vijayaraghavan18.4:
Concentrating Solar Thermal Power / Manuel Romero-Alvarez ; Eduardo Zarza19:
Introduction and Context / 19.1:
Solar Concentration and CSP Systems / 19.2:
Solar Concentrator Beam Quality / 19.3:
Solar Concentration Ratio: Principles and Limitations of CSP Systems / 19.4:
Solar Thermal Power Plant Technologies / 19.5:
Parabolic Trough Solar Thermal Power Plants / 19.6:
Central Receiver Solar Thermal Power Plants / 19.7:
Volumetric Atmospheric Receivers: PHOEBUS and Solair / 19.8:
Solar Air Preheating Systems for Combustion Turbines: The SOLGATE Project / 19.9:
Dish/Stirling Systems / 19.10:
Market Opportunities / 19.11:
Photovoltaics Fundamentals, Technology and Application / 19.12:
Photovoltaics / Roger Messenger20.1:
Thin-Film PV Technology / Hari M. Upadhyaya ; Takhir M. Razykov ; Ayodhya N. Tiwari20.2:
Concentrating PV Technologies / Roland Winston ; Robert McConnell20.3:
Wind Energy Conversion / 21:
Wind Turbine Aerodynamics / 21.1:
Wind Turbine Loads / 21.3:
Wind Turbine Structural Dynamic Considerations / 21.4:
Peak Power Limitation / 21.5:
Turbine Subsystems / 21.6:
Other Wind-Energy Conversion Considerations / 21.7:
Biomass Conversion Processes For Energy Recovery / 22:
Energy Recovery by Anaerobic Digestion / Massoud Kayhanian ; George Tchobanoglous22.1:
Power Generation / Robert C. Brown22.2:
Biofuels / 22.3:
Geothermal Power Generation / Kevin Kitz23:
Definition and Use of Geothermal Energy / 23.1:
Requirements for Commercial Geothermal Power Production / 23.3:
Exploration and Assessment of Geothermal Resources / 23.4:
Management of the Geothermal Resource for Power Production / 23.5:
Geothermal Steam Supply (from Wellhead to Turbine) / 23.6:
Geothermal Power Production-Steam Turbine Technologies / 23.7:
Geothermal Power Production-Binary Power Plant Technologies / 23.8:
Environmental Impact / 23.9:
Additional Information on Geothermal Energy / 23.10:
Waste-to-Energy Combustion / Charles O. Velzy ; Leonard M. Grillo24:
Waste Quantities and Characteristics / 24.1:
Design of WTE Facilities / 24.3:
Air Pollution Control Facilities / 24.4:
Performance / 24.5:
Costs / 24.6:
Status of Other Technologies / 24.7:
Future Issues and Trends / 24.8:
Ocean Energy Technology / Desikan Bharathan ; Federica Zangrando25:
Ocean Thermal Energy Conversion / 25.1:
Tidal Power / 25.2:
Wave Power / 25.3:
Concluding Remarks / 25.4:
Fuel Cells / Xianguo Li26:
Principle of Operation for Fuel Cells / 26.1:
Typical Fuel Cell Systems / 26.3:
Performance of Fuel Cells / 26.4:
Fuel Cell Electrode Processes / 26.5:
Cell Connection and Stack Design Considerations / 26.6:
Six Major Types of Fuel Cells / 26.7:
Direct Energy Conversion / 26.8:
Thermionic Energy Conversion / Mysore L. Ramalingam27.1:
Thermoelectric Power Conversion / Jean-Pierre Fleurial27.2:
Magnetohydrodynamic Power Generation / William D. Jackson27.3:
Appendices / Nitin Goel
The International System of Units, Fundamental Constants, and Conversion Factors / Appendix 1:
Properties of Gases, Vapors, Liquids and Solids / Appendix 2:
Ultimate Analysis of Biomass Fuels / Appendix 4:
Index
Introduction / D. Yogi Goswami1:
Energy Use by Sectors / 1.1:
Electrical Capacity Additions to 2030 / 1.2:
3.

図書

図書
editors, Dunwei Wang, Guozhong Cao
出版情報: London : World Scientific, c2018  xiii, 821 p. ; 24 cm
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Preface
About the Editors
The Principle of Photoelectrochemical Water Splitting / Peiyan Ma ; Dunwei WangChapter 1:
Semiconducting Photocatalysis for Solar Hydrogen Conversion / Shaohua Shen ; Jie ChenChapter 2:
Visible-Tight-Driven Photocatalysis / Qingzhe Zhang ; Yanlong Liu ; Zhenhe Xu ; Yue Zhao ; Mohamed Choker ; Dongling MaChapter 3:
Metal Nitride Nanostructures: Emerging Catalysts for Artificial Photosynthesis / Md Golarn Kibria ; Bandar AlOtaibi ; Zetian MiChapter 4:
Surface Engineering of Semiconductors for Photoelectrochemical Water Splitting / Gongming Wang ; Yi Yang ; Yat LiChapter 5:
Photoanodic and Photocathodic Materials Applied for Free-Running Solar Water Splitting Devices / Miao Zhong ; Hiroyuki Kaneko ; Taro Yamada ; Kazunari DomenChapter 6:
Electrocatalytic Processes in Energy Technologies / Yang Huang ; Min Zeng ; Qiufang Gong ; Yanguang LiChapter 7:
Soft X-ray Spectroscopy on Photocatalysis / Yi-Sheng Liu ; Cheng-Hao Chuang ; Jinghua GuoChapter 8:
Photoelectrochemical Tools for the Assessment of Energy Conversion Devices / Isaac Herraiz-Cardona ; Sixto GimenezChapter 9:
Fundamentals of Rechargeable Batteries and Electrochemical Potentials of Electrode Materials / Chaofeng Liu ; Guozhong CaoChapter 10:
Revitalized Interest in Vanadium Pentoxide as Cathode Material for Alkali-Ion Batteries / Yanwei Li ; Jinhuan Yao ; Robert C. Massé ; Evan UchakerChapter 11:
Tin-Based Compounds as Anode Materials for Lithium-Ion Storage / Ming ZhangChapter 12:
Beyond Li Ion: Electrode Materials for Sodium- and Magnesium-Ion Batteries / Robert MasséChapter 13:
Nanomaterials and Nanostructures for Regulating Ions and Electron Transport in Advanced Energy Storage Devices / Yu Wang ; Wei-Hong ZhongChapter 14:
Index
Preface
About the Editors
The Principle of Photoelectrochemical Water Splitting / Peiyan Ma ; Dunwei WangChapter 1:
4.

図書

図書
Tatsuhiro Okada, Masao Kaneko, editors
出版情報: Berlin : Springer, c2009  xxiv, 431 p. ; 25 cm
シリーズ名: Springer series in materials science ; v. 111
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Preface
List of Contributors
List of Abbreviations
Historical Overview and Fundamental Aspects of Molecular Catalysts for Energy Conversion / T. Okada ; T. Abe ; M. Kaneko1:
Introduction: Why Molecular Catalysts? A New Era of Biomimetic Approach Toward Efficient Energy Conversion Systems / 1.1:
Molecular Catalysts for Fuel Cell Reactions / 1.2:
Oxygen Reduction Catalysts / 1.2.1:
Fuel Oxidation Catalysts / 1.2.2:
Molecular Catalysts for Artificial Photosynthetic Reaction / 1.3:
Water Oxidation Catalyst / 1.3.1:
Reduction Catalyst / 1.3.2:
Photodevices for Photoinduced Chemical Reaction in the Water Phase / 1.3.3:
Summary / 1.4:
References
Charge Transport in Molecular Catalysis in a Heterogeneous Phase / 2:
Introduction / 2.1:
Charge Transport (CT) by Molecules in a Heterogeneous Phase / 2.2:
General Overview / 2.2.1:
Mechanism of Charge Transport / 2.2.2:
Charge Transfer by Molecules Under Photoexcited State in a Heterogeneous Phase / 2.3:
Overview / 2.3.1:
Mechanism of Charge Transfer at Photoexcited State in a Heterogeneous Phase / 2.3.2:
Charge Transfer and Electrochemical Reactions in Metal Complexes / 2.4:
Charge Transfer in Metal Complexes / 2.4.1:
Charge Transfer at Electrode Surfaces / 2.4.2:
Oxygen Reduction Reaction at Metal Macrocycles / 2.4.3:
Proton Transport in Polymer Electrolytes / 2.5:
Proton Transfer Reactions / 2.5.1:
Electrochemical Methods for Catalyst Evaluation in Fuel Cells and Solar Cells / 2.5.2:
Electrochemical Measuring System for Catalyst Research in Fuel Cells / 3.1:
Reference Electrode / 3.2.1:
Rotating Ring-Disk Electrode / 3.2.2:
Gas Electrodes of Half-Cell Configuration / 3.2.3:
Fuel Cell Test Station / 3.2.4:
Electrochemical Methods for Electrocatalysts / 3.2.5:
Electrochemical Measuring System for Heterogeneous Charge Transport and Solar Cells / 3.3:
Testing Method of Charge Transport in Heterogeneous Systems / 3.3.1:
Evaluation of Charge Transport by Redox Molecules Incorporated in a Heterogeneous Phase / 3.3.2:
AC Impedance Spectroscopy to Evaluate Charge Transport, Conductivity, Double-Layer Capacitance, and Electrode Reaction / 3.3.3:
I-V Characteristics of Solar Cells / 3.3.4:
Impedance Spectroscopy to Evaluate Multistep Charge Transport of a Dye-Sensitized Solar Cell / 3.3.5:
Molecular Catalysts for Fuel Cell Anodes / 3.4:
Concept of Composite Electrocatalysts in Fuel Cells / 4.1:
Methanol Oxidation Reaction / 4.3:
Mechanism of Methanol Oxidation Reaction / 4.3.1:
New Electrocatalysts for Methanol Oxidation Reaction / 4.3.2:
Structure of Composite Catalysts / 4.3.3:
Formic Acid Oxidation Reaction / 4.4:
Mechanism of Formic Acid Oxidation / 4.4.1:
Formic Acid Oxidation on Composite Catalysts / 4.4.2:
CO-Tolerant Electrocatalysts for Hydrogen Oxidation Reaction / 4.5:
Electrochemical and Fuel Cell Testing / 4.5.1:
Durability Testing / 4.5.2:
Structural Characterization / 4.5.3:
Macrocycles for Fuel Cell Cathodes / K. Oyaizu ; H. Murata ; M. Yuasa4.6:
Molecular Design of Macrocycles for Fuel Cell Cathodes / 5.1:
Diporphyrin Cobalt Complexes and Related Catalysts / 5.3:
Diporphyrin Cobalt Complexes / 5.3.1:
Polypyrrole Cobalt Complexes / 5.3.2:
Cobalt Thienylporphyrins / 5.3.3:
Porphyrin Assemblies Based on Intermolecular Interaction / 5.4:
Multinuclear Complexes as Electron Reservoirs / 5.5:
Platinum-Free Catalysts for Fuel Cell Cathode / N. Koshino ; H. Higashimura5.6:
Drawbacks of Using Pt as Catalysts in PEFC / 6.1:
Mechanistic Aspects of Oxygen Reduction by Cathode Catalyst / 6.3:
Metal Particles / 6.4:
Metal Oxides, Carbides, Nitrides, and Chalcogenides / 6.4.2:
Carbon Materials / 6.4.3:
Metal Complex-Based Catalysts / 6.4.4:
Catalysts Designed from Dinuclear Metal Complexes / 6.4.5:
Novel Support Materials for Fuel Cell Catalysts / J. Nakamura6.5:
Performance of Electrocatalysts Using Carbon Nanotubes / 7.1:
<$>H_2 -O_2<$> Fuel Cell / 7.2.1:
DMFC / 7.2.2:
Why Is Carbon Nanotube So Effective as Support Material? / 7.3:
Molecular Catalysts for Electrochemical Solar Cells and Artificial Photosynthesis / 8:
Overview on Principles of Molecule-Based Solar Cells / 8.1:
Photon Absorption / 8.2.1:
Suppression of Charge Recombination to Achieve Effective Charge Separation / 8.2.2:
Diffusion of Separated Charges / 8.2.3:
Electrode Reaction / 8.2.4:
Dye-Sensitized Solar Cell (DSSC) / 8.3:
Artificial Photosynthesis / 8.4:
Dark Catalysis for Artificial Photosynthesis / 8.5:
Dark Catalysis for Water Oxidation / 8.5.1:
Dark Catalysis for Proton Reduction / 8.5.2:
Conclusion and Future Scopes / 8.6:
Molecular Design of Sensitizers for Dye-Sensitized Solar Cells / K. Hara9:
Metal-Complex Sensitizers / 9.1:
Molecular Structures of Ru-Complex Sensitizers / 9.2.1:
Electron-Transfer Processes / 9.2.2:
Performance of DSSCs Based on Ru Complexes / 9.2.3:
Other Metal-Complex Sensitizers for DSSCs / 9.2.4:
Porphyrins and Phthalocyanines / 9.3:
Organic Dyes / 9.4:
Molecular Structures of Organic-Dye Sensitizers for DSSCs / 9.4.1:
Performance of DSSCs Based on Organic Dyes / 9.4.2:
Electron Transfer from Organic Dyes to TiO2 / 9.4.3:
Electron Diffusion Length / 9.4.4:
Stability / 9.5:
Photochemical and Thermal Stability of Sensitizers / 9.5.1:
Long-Term Stability of Solar-Cell Performance / 9.5.2:
Summary and Perspectives / 9.6:
Fabrication of Charge Carrier Paths for High Efficiency Cells / T. Kogo ; Y. Ogomi ; S. Hayase10:
Fabrication of Electron-Paths / 10.1:
Suppression of Black-Dye Aggregation in a Pressurized CO2 Atmosphere / 10.3:
Two-Layer TiO2 Structure for Efficient Light Harvesting / 10.4:
TCO-Less All-Metal Electrode-Type DSC / 10.5:
Ion-Path in Quasi-Solid Medium / 10.6:
Environmental Cleaning by Molecular Photocatalysts / D. Wöhrle ; K. Nagai ; O. Suvorova ; R. Gerdes10.7:
Oxidative Methods for the Photodegradation of Pollutants in Wastewater / 11.1:
Comparison of Different Methods of UV Processes for Water Cleaning / 11.2.1:
Photodegradation of Pollutants with Oxygen in the Visible Region of Light / 11.2.2:
Visible Light Decomposition of Ammonia to Nitrogen with Ru(bpy)32+ as Sensitizer / 11.3:
Nitrogen Pollutants and Their Photodecomposition / 11.3.1:
Photochemical Electron Relay with Ammonia / 11.3.2:
Photochemical Decomposition of Ammonia to Dinitrogen by a Photosensitized Electron Relay / 11.3.3:
Visible Light Responsive Organic Semiconductors as Photocatalysts / 11.4:
Photoelectrochemical Character of Organic Semiconductors in Water Phase / 11.4.1:
Photoelectrochemical Oxidations by Irradiation with Visible Light / 11.4.2:
Photochemical Decomposition of Amines Using Visible Light and Organic Semiconductors / 11.4.3:
Optical Oxygen Sensor / N. Asakura ; I. Okura12:
Theoretical Aspect of Optical Oxygen Sensor of Porphyrins / 12.1:
Advantage of Optical Oxygen Sensing / 12.2.1:
Principle of Optical Oxygen Sensor / 12.2.2:
Brief History of Optical Oxygen Sensors / 12.2.3:
Optical Oxygen Sensor by Phosphorescence Intensity / 12.3:
Phosphorescent Compounds / 12.3.1:
Immobilization of Phosphorescent Molecules for Optical Oxygen Sensor and Measurement System / 12.3.2:
Optical Oxygen Sensor with Platinum Octaethylporphyrin Polystyrene Film (PtOEP-PS Film) / 12.3.3:
Optical Oxygen Sensor with PtOEP and Supports / 12.3.4:
Application of Optical Oxygen Sensor for Air Pressure Measurements / 12.3.5:
Optical Oxygen Sensor by Phosphorescence Lifetime Measurements / 12.4:
Advantages of Phosphorescence Lifetime Measurement / 12.4.1:
Phosphorescence Lifetime Measurement / 12.4.2:
Distribution of Oxygen Concentration Inside Single Living Cell by Phosphorescence Lifetime Measurement / 12.4.3:
Optical Oxygen Sensor T-T Absorption / 12.5:
Advantage of Optical Oxygen Sensor Based on T-T Absorption / 12.5.1:
Optical Oxygen Sensor Based on the Photoexcited Triplet Lifetime Measurement / 12.5.2:
Optical Oxygen Sensor Based on Stationary T-T Absorption (Stationary Quenching) / 12.5.3:
Adsorption and Electrode Processes / H. Shiroishi12.6:
Adsorption Isotherms and Kinetics / 13.1:
Langmuir Isotherms / 13.2.1:
Freundlich Isotherm / 13.2.2:
Temkin Isotherm / 13.2.3:
Application for Selective Reaction on Metal Surface by Adsorbate / 13.2.4:
Slab Optical Waveguide Spectroscopy / 13.3:
Principle / 13.3.1:
Application of Slab Optical Waveguide Spectroscopy / 13.3.2:
Methods of Digital Simulation for Electrochemical Measurements / 13.4:
Formulation of Electrochemical System / 13.4.1:
Finite Differential Methods / 13.4.2:
Digital Simulation for Polymer-Coated Electrodes / 13.5:
Hydrostatic Condition / 13.5.1:
Hydrodynamic Condition / 13.5.2:
Classical Monte Carlo Simulation for Charge Propagation in Redox Polymer / 13.6:
Visualization of Charge Propagation / 13.6.1:
Determination of a Charge Hopping Distance / 13.6.2:
Spectroscopic Studies of Molecular Processeson Electrocatalysts / A. Kuzume ; M. Ito14:
The Preparation and Spectroscopic Characterization of Fuel Cell Catalysts / 14.1:
Catalyst Preparation by Electroless Plating and Direct Hydrogen Reduction Methods: Practical Application for High Performance PEFC / 14.2.1:
In Situ IRAS Studies of Methanol Oxidation on Fuel Cell Catalysts / 14.2.2:
Spectroscopic Studies of Methanol Oxidation on Pt Surfaces / 14.3:
Electrooxidation of Methanol on Pt(111) in Acid Solutions: Effects of Electrolyte Anions during Electrocatalytic Reactions / 14.3.1:
Methanol Oxidation Mechanisms on Pt(111) Surfaces / 14.3.2:
Conclusions / 14.4:
Strategies for Structural and Energy Calculation of Molecular Catalysts / S. Tsuzuki ; M. Saito15:
Computational Methods / 15.1:
Basis Set and Electron Correlation Effects on Geometry and Conformational Energy / 15.3:
Intermolecular Forces / 15.4:
Basis and Electron Correlation Effects on Intermolecular Interactions / 15.5:
Calculations of Transition Metal Complexes / 15.6:
Examples of the Ab Initio Calculation for Molecular Catalysts / 15.7:
Future Technologies on Molecular Catalysts / 15.8:
Road Map for Clean Energy Society / 16.1:
Hydrogen Production / 16.3:
Natural Gas / 16.3.1:
Renewable Energy Source / 16.3.2:
Biomass / 16.3.3:
Hydrogen Utilization / 16.4:
Hydrogen Storage / 16.4.1:
Energy Conversion / 16.4.2:
Biomimetic Approach and Role of Molecular Catalysts for Energy-Efficient Utilization / 16.5:
Index / 16.6:
Preface
List of Contributors
List of Abbreviations
5.

図書

図書
Kinji Asaka, Hidenori Okuzaki, editors
出版情報: Singapore : Springer, c2019  x, 740 p. ; 25 cm
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