| Preface |
| Foreword to the first edition / 1: |
| Introduction |
| Acknowledgements / 2: |
| Efficiency and Open Circuit Voltage |
| Abbreviations / 3: |
| Operational Fuel Cell Voltages |
| Symbols / 4: |
| Proton Exchange Membrane Fuel Cells |
| Alkaline Electrolyte Fuel Cells / 5: |
| Medium and High Temperature Fuel cells / 6: |
| Hydrogen Fuel Cells--Basic Principles / 7: |
| Fuelling fuel cells |
| Compressors, Turbines, Ejectors, Fans, Blowers and Pumps / 1.2: |
| What Limits the Current? |
| Delivering Fuel Cell Power / 9: |
| Connecting Cells in Series--the Bipolar Plate / 10: |
| Change in Molar Gibbs Free Energy Calculations |
| Useful Fuel Cell Equations / 1.4: |
| Gas Supply and Cooling |
| Index / 12: |
| Fuel Cell Types |
| Other Cells--Some Fuel Cells, Some Not / 1.6: |
| Biological fuel cells / 1.6.1: |
| Metal/air cells / 1.6.2: |
| Redox flow cells or regenerative fuel cells / 1.6.3: |
| Other Parts of a Fuel Cell System / 1.7: |
| Figures Used to Compare Systems / 1.8: |
| Advantages and Applications / 1.9: |
| References |
| Energy and the EMF of the Hydrogen Fuel Cell / 2.1: |
| The Open Circuit Voltage of Other Fuel Cells and Batteries / 2.2: |
| Efficiency and Efficiency Limits / 2.3: |
| Efficiency and the Fuel Cell Voltage / 2.4: |
| The Effect of Pressure and Gas Concentration / 2.5: |
| The Nernst equation / 2.5.1: |
| Hydrogen partial pressure / 2.5.2: |
| Fuel and oxidant utilisation / 2.5.3: |
| System pressure / 2.5.4: |
| An application--blood alcohol measurement / 2.5.5: |
| Summary / 2.6: |
| Terminology / 3.1: |
| Fuel Cell Irreversibilities--Causes of Voltage Drop / 3.3: |
| Activation Losses / 3.4: |
| The Tafel equation / 3.4.1: |
| The constants in the Tafel equation / 3.4.2: |
| Reducing the activation overvoltage / 3.4.3: |
| Summary of activation overvoltage / 3.4.4: |
| Fuel Crossover and Internal Currents / 3.5: |
| Ohmic Losses / 3.6: |
| Mass Transport or Concentration Losses / 3.7: |
| Combining the Irreversibilities / 3.8: |
| The Charge Double Layer / 3.9: |
| Distinguishing the Different Irreversibilities / 3.10: |
| Overview / 4.1: |
| How the Polymer Electrolyte Works / 4.2: |
| Electrodes and Electrode Structure / 4.3: |
| Water Management in the PEMFC / 4.4: |
| Overview of the problem / 4.4.1: |
| Airflow and water evaporation / 4.4.2: |
| Humidity of PEMFC air / 4.4.3: |
| Running PEM fuel cells without extra humidification / 4.4.4: |
| External humidification--principles / 4.4.5: |
| External humidification--methods / 4.4.6: |
| PEM Fuel Cell Cooling and Air Supply / 4.5: |
| Cooling using the cathode air supply / 4.5.1: |
| Separate reactant and cooling air / 4.5.2: |
| Water cooling of PEM fuel cells / 4.5.3: |
| PEM Fuel Cell Connection--the Bipolar Plate / 4.6: |
| Flow field patterns on the bipolar plates / 4.6.1: |
| Making bipolar plates for PEM fuel cells / 4.6.3: |
| Other topologies / 4.6.4: |
| Operating Pressure / 4.7: |
| Outline of the problem / 4.7.1: |
| Simple quantitative cost/benefit analysis of higher operating pressures / 4.7.2: |
| Other factors affecting choice of pressure / 4.7.3: |
| Reactant Composition / 4.8: |
| Carbon monoxide poisoning / 4.8.1: |
| Methanol and other liquid fuels / 4.8.2: |
| Using pure oxygen in place of air / 4.8.3: |
| Example Systems / 4.9: |
| Small 12-W system / 4.9.1: |
| Medium 2-kW system / 4.9.2: |
| 205-kW fuel cell engine / 4.9.3: |
| Historical Background and Overview / 5.1: |
| Basic principles / 5.1.1: |
| Historical importance / 5.1.2: |
| Main advantages / 5.1.3: |
| Types of Alkaline Electrolyte Fuel Cell / 5.2: |
| Mobile electrolyte / 5.2.1: |
| Static electrolyte alkaline fuel cells / 5.2.2: |
| Dissolved fuel alkaline fuel cells / 5.2.3: |
| Operating Pressure and Temperature / 5.3: |
| Electrodes for Alkaline Electrolyte Fuel Cells / 5.4: |
| Sintered nickel powder / 5.4.1: |
| Raney metals / 5.4.3: |
| Rolled electrodes / 5.4.4: |
| Cell Interconnections / 5.5: |
| Problems and Development / 5.6: |
| Direct Methanol Fuel Cells |
| Anode Reaction and Catalysts / 6.1: |
| Overall DMFC reaction / 6.2.1: |
| Anode reactions in the alkaline DMFC / 6.2.2: |
| Anode reactions in the PEM direct methanol FC / 6.2.3: |
| Anode fuel feed / 6.2.4: |
| Anode catalysts / 6.2.5: |
| Electrolyte and Fuel Crossover / 6.3: |
| How fuel crossover occurs / 6.3.1: |
| Standard techniques for reducing fuel crossover / 6.3.2: |
| Fuel crossover techniques in development / 6.3.3: |
| Cathode Reactions and Catalysts / 6.4: |
| Methanol Production, Storage, and Safety / 6.5: |
| Methanol production / 6.5.1: |
| Methanol safety / 6.5.2: |
| Methanol compared to ethanol / 6.5.3: |
| Methanol storage / 6.5.4: |
| Direct Methanol Fuel Cell Applications / 6.6: |
| Medium and High Temperature Fuel Cells |
| Common Features / 7.1: |
| An introduction to fuel reforming / 7.2.1: |
| Fuel utilisation / 7.2.2: |
| Bottoming cycles / 7.2.3: |
| The use of heat exchangers--exergy and pinch technology / 7.2.4: |
| The Phosphoric Acid Fuel Cell (PAFC) / 7.3: |
| How it works / 7.3.1: |
| Performance of the PAFC / 7.3.2: |
| Recent developments in PAFC / 7.3.3: |
| The Molten Carbonate Fuel Cell (MCFC) / 7.4: |
| Implications of using a molten carbonate electrolyte / 7.4.1: |
| Cell components in the MCFC / 7.4.3: |
| Stack configuration and sealing / 7.4.4: |
| Internal reforming / 7.4.5: |
| Performance of MCFCS / 7.4.6: |
| Practical MCFC systems / 7.4.7: |
| The Solid Oxide Fuel Cell / 7.5: |
| SOFC components / 7.5.1: |
| Practical design and stacking arrangements for the SOFC / 7.5.3: |
| SOFC performance / 7.5.4: |
| SOFC combined cycles, novel system designs and hybrid systems / 7.5.5: |
| Intermediate temperature SOFCs / 7.5.6: |
| Fuelling Fuel Cells |
| Fossil Fuels / 8.1: |
| Petroleum / 8.2.1: |
| Petroleum in mixtures: tar sands, oil shales, gas hydrates, and LPG / 8.2.2: |
| Coal and coal gases / 8.2.3: |
| Natural gas / 8.2.4: |
| Bio-Fuels / 8.3: |
| The Basics of Fuel Processing / 8.4: |
| Fuel cell requirements / 8.4.1: |
| Desulphurisation / 8.4.2: |
| Steam reforming / 8.4.3: |
| Carbon formation and pre-reforming / 8.4.4: |
| Direct hydrocarbon oxidation / 8.4.5: |
| Partial oxidation and autothermal reforming / 8.4.7: |
| Hydrogen generation by pyrolysis or thermal cracking of hydrocarbons / 8.4.8: |
| Further fuel processing--carbon monoxide removal / 8.4.9: |
| Practical Fuel Processing--Stationary Applications / 8.5: |
| Conventional industrial steam reforming / 8.5.1: |
| System designs for natural gas fed PEMFC and PAFC plants with steam reformers / 8.5.2: |
| Reformer and partial oxidation designs / 8.5.3: |
| Practical Fuel Processing--Mobile Applications / 8.6: |
| General issues / 8.6.1: |
| Methanol reforming for vehicles / 8.6.2: |
| Micro-scale methanol reactors / 8.6.3: |
| Gasoline reforming / 8.6.4: |
| Electrolysers / 8.7: |
| Operation of electrolysers / 8.7.1: |
| Applications of electrolysers / 8.7.2: |
| Electrolyser efficiency / 8.7.3: |
| Generating at high pressure / 8.7.4: |
| Photo-electrolysis / 8.7.5: |
| Biological Production of Hydrogen / 8.8: |
| Photosynthesis / 8.8.1: |
| Hydrogen production by digestion processes / 8.8.3: |
| Hydrogen Storage I--Storage as Hydrogen / 8.9: |
| Introduction to the problem / 8.9.1: |
| Safety / 8.9.2: |
| The storage of hydrogen as a compressed gas / 8.9.3: |
| Storage of hydrogen as a liquid / 8.9.4: |
| Reversible metal hydride hydrogen stores / 8.9.5: |
| Carbon nanofibres / 8.9.6: |
| Storage methods compared / 8.9.7: |
| Hydrogen Storage II--Chemical Methods / 8.10: |
| Methanol / 8.10.1: |
| Alkali metal hydrides / 8.10.3: |
| Sodium borohydride / 8.10.4: |
| Ammonia / 8.10.5: |
| Compressors, Turbines, Ejectors, Fans, Blowers, and Pumps / 8.10.6: |
| Compressors--Types Used / 9.1: |
| Compressor Efficiency / 9.3: |
| Compressor Power / 9.4: |
| Compressor Performance Charts / 9.5: |
| Performance Charts for Centrifugal Compressors / 9.6: |
| Compressor Selection--Practical Issues / 9.7: |
| Turbines / 9.8: |
| Turbochargers / 9.9: |
| Ejector Circulators / 9.10: |
| Fans and Blowers / 9.11: |
| Membrane/Diaphragm Pumps / 9.12: |
| DC Regulation and Voltage Conversion / 10.1: |
| Switching devices / 10.2.1: |
| Switching regulators / 10.2.2: |
| Inverters / 10.3: |
| Single phase / 10.3.1: |
| Three phase / 10.3.2: |
| Regulatory issues and tariffs / 10.3.3: |
| Power factor correction / 10.3.4: |
| Electric Motors / 10.4: |
| General points / 10.4.1: |
| The induction motor / 10.4.2: |
| The brushless DC motor / 10.4.3: |
| Switched reluctance motors / 10.4.4: |
| Motors efficiency / 10.4.5: |
| Motor mass / 10.4.6: |
| Fuel Cell/Battery or Capacitor Hybrid Systems / 10.5: |
| Fuel Cell Systems Analysed |
| Energy Systems / 11.1: |
| Well-To-Wheels Analysis / 11.3: |
| Importance of well-to-wheels analysis / 11.3.1: |
| Well-to-tank analysis / 11.3.2: |
| Main conclusions of the GM well-to-wheels study / 11.3.3: |
| Power-Train or Drive-Train Analysis / 11.4: |
| Example System I--PEMFC Powered Bus / 11.5: |
| Example System II--Stationary Natural Gas Fuelled System / 11.6: |
| Flow sheet and conceptual systems designs / 11.6.1: |
| Detailed engineering designs / 11.6.3: |
| Further systems analysis / 11.6.4: |
| Closing Remarks / 11.7: |
| Hydrogen Fuel Cell / Appendix 1: |
| The Carbon Monoxide Fuel Cell / A1.2: |
| Oxygen and Air Usage / Appendix 2: |
| Air Exit Flow Rate / A2.3: |
| Hydrogen Usage / A2.4: |
| Water Production / A2.5: |
| Heat Produced / A2.6: |
EB
