Preface xv Acknowledgement xvii List of Figures xix Author Biography xxxi 1 Overall Energy Perspective 1 1.1 Introduction 1 1.2 Energy Overview 2 1.3 Sun as the Source of All Energy 4 1.4 Energy Consumption in Transport, Agriculture and Domestic Sectors 6 1.5 Energy Crisis: Starvation of Fossil Fuels 8 1.6 Environmental Degradation Due to Fossil Fuel Combustion 9 1.6.
1 Green House Effect: Greenhouse Gas and Global Warming 10 1.6.2 Smog 15 1.6.3 Acid Rain 17 1.6.4 Vehicular Pollution 18 1.7 Energy Transition Towards Sustainability 19 1.
8 Role of Hydrogen in Present Energy-environment Context 21 1.9 Demand for Hydrogen 22 1.10 Structure and Phases of Hydrogen 25 1.11 Discovery and Occurrence of Hydrogen 27 1.12 Uses of Hydrogen 28 Concluding Remarks 32 Abbreviations 33 References 34 2 Hydrogen Energy: Properties and Quality 37 2.1 Introduction 37 2.2 Properties of Hydrogen 39 2.3 Physical Properties 40 2.
4 Chemical Properties 44 2.4.1 Flammability Limit 46 2.4.2 Minimum Ignition Energy 47 2.4.3 Flashpoint 48 2.4.
4 Auto-ignition Temperature 48 2.4.5 Octane Number 49 2.4.6 Heat of Combustion 49 2.5 Electro-conductivity and the Joule-Thomson Effect 50 2.6 Emissivity of Hydrogen Flame and Adiabatic Flame Temperature 50 2.7 Laminar Burning Velocity 51 2.
8 Hydrogen-Oxygen Reaction Mechanism 51 2.9 Hydrogen Colours and Carbon Footprint 53 2.10 Grey, Blue and Green Hydrogen 54 2.10.1 Grey Hydrogen 54 2.10.2 Blue Hydrogen 55 2.10.
3 Turquoise, Brown, Black, Pink, Red, Yellow and White Hydrogen 58 2.11 Green Hydrogen 59 2.12 Benefits of Green Hydrogen 63 2.13 Obstacles and Challenges to Green Hydrogen 65 2.14 Cost of Green Hydrogen 67 Concluding Remarks 70 Abbreviations 72 References 72 3 Production of Hydrogen 75 3.1 Introduction 76 3.2 Routes of Hydrogen Production 76 3.3 Steam Methane Reforming (SMR) 80 3.
3.1 Water-Gas Shift Reactor 82 3.3.2 Selection of Catalysts 83 3.3.3 Ethanol and Methanol Steam Reforming 83 3.3.4 Fuel Processing for Fuel Cell Application 84 3.
4 Partial Oxidation of POx 85 3.5 Partial Oxidation of Heavy Oils and Naphtha 86 3.6 Auto-thermic Reaction (ATR) 86 3.7 Hydrogen from Coal Gasification 88 3.7.1 Types of Coal Gasification 88 3.7.2 Mechanism of Hydrogen Production by Gasification 89 3.
8 Underground Coal Gasification 89 3.9 Hydrogen Production from Biomass 90 3.9.1 Thermochemical Conversion of Biomass to Hydrogen 91 3.9.2 Gasification of Biomass 91 3.9.3 Plasma Gasification Process 93 3.
9.4 Pyrolysis of Biomass 93 3.9.5 Supercritical Water Gasification of Biomass (SWGB) 94 3.10 Biological Production of Hydrogen 95 3.10.1 Biophotolysis 96 3.10.
2 Photo-fermentation 97 3.10.3 Dark Fermentation 98 3.10.4 Combined Dark-Photo Co-fermentation 98 3.11 Hydrogen Production Based on Electrolysis 99 3.11.1 AEL and PEM Electrolysis 100 3.
11.2 Alkaline Electrolysis 102 3.11.3 Polymer Electrolyte Membrane Electrolysis 102 3.12 Hydrogen Production Using Solar Energy 105 3.12.1 Solar Thermal Methane Splitting 106 3.13 Solid Oxide Electrolyser 106 3.
14 Seawater Electrolyser 106 3.14.1 Photo-electrolysis (Photolysis) 107 3.15 Hydrogen Generation Using Wind Energy 108 3.16 Ocean Thermal Energy Conversion for Hydrogen Production 109 3.17 Geothermal Energy for Hydrogen Production 109 3.18 Hydrogen from H2S in Black Sea Waters 110 3.19 Hydrogen Production Using Enterobacter cloacae 111 3.
20 Hydrogen Production by Reforming Natural Gas and Bio-derived Liquids Using a Dense Ceramic Membrane 112 3.21 Plasma Reforming 113 3.22 Hydrogen from Nuclear Energy 114 3.23 Ammonia Dissociation 117 3.24 Hydrogen from Methane Hydrate 118 3.25 Improvements in Catalysts for Hydrogen Production 119 3.26 An Assessment of GWP and AP in Various Hydrogen Production Processes 120 Concluding Remarks and Future Outlook 122 Abbreviations 123 References 124 4 Hydrogen Storage, Transportation, Delivery and Distribution 133 4.1 Introduction 134 4.
2 Properties of Hydrogen Relevant to Storage 134 4.3 Hydrogen Storage Criteria for Specific Application 136 4.4 Storage of Hydrogen as Compressed Gas 138 4.4.1 Types of Gas Cylinders 139 4.5 Liquid Hydrogen Storage 141 4.5.1 Boil-off Losses 141 4.
5.2 Storage in High-pressure Gas Cylinders: Benefits and Challenges 143 4.6 Underground Storage of Hydrogen 144 4.7 Liquid Hydrogen Storage 146 4.7.1 Design Features of Storage Vessels 148 4.8 Slush Hydrogen Storage 149 4.9 Hydrides 150 4.
10 Hydrogen Storage in Zeolites 154 4.11 Chemical Hydrides 154 4.12 Nanomaterials for Hydrogen Storage 155 4.13 Hydrogen Storage in Hollow Microspheres 156 4.14 Hydrogen Transportation 157 4.14.1 Transport of Liquid and Gaseous Hydrogen 158 4.14.
2 Hydrogen Transport Through Pipelines and Ships 158 4.14.3 Hydrogen Storage in Vehicles 160 4.15 Transport of Gaseous Hydrogen 161 4.16 Liquid Hydrogen 162 4.17 Hydrogen Dispensing 163 4.18 Distribution and Delivery 164 Concluding Remarks 166 Abbreviations 167 References 167 5 Safety, Sensing and Detection of Hydrogen 173 5.1 Introduction 173 5.
2 Infamous Disasters Related to Hydrogen Safety 174 5.3 Classification of Hazards 179 5.4 Physiological Hazards 179 5.4.1 Asphyxiation 180 5.4.2 Hypothermia 180 5.4.
3 Thermal and Cryogenic Burns 180 5.5 Properties Relevant to Hydrogen Safety 181 5.5.1 Density, Buoyancy and Diffusivity 183 5.5.2 Continuous Evaporation and High Vapour Density 186 5.5.3 Pressure Rise 187 5.
5.4 Maximum Experimental Safe Gap (MESG) 188 5.5.5 Quenching Distance and Quenching Limit 188 5.5.6 Ignition Energy 190 5.5.7 Thermal Energy and Radiation 192 5.
5.8 Excessive Pressure and Blast Waves 193 5.5.9 Burning Velocity 194 5.5.10 Flammability Range 196 5.6 Phenomena of Explosion 197 5.7 Deflagration and Detonation 198 5.
8 Safety at Different Stages: Production, Transmission, Storage and Application 201 5.8.1 Safety During Production 202 5.8.2 Safety Criteria in Storage 203 5.8.3 Safety in Transmission 204 5.9 Safe Handling, Storage and Use of Hydrogen in Vehicles 205 5.
10 Hydrogen Leak Detection Technique and Sensors 208 5.11 Hydrogen Embrittlement 214 Concluding Remarks 215 Abbreviations 216 References 216 6 Application of Hydrogen Energy 221 6.1 Introduction 222 6.2 Ammonia Production and Fertiliser Industry 225 6.3 Production of Methanol 227 6.4 Hydrogen in Refineries 228 6.5 Hydrogen Use in Steel Industries 229 6.6 Hydrogen in Agriculture, Healthcare, Food Industry and Several Other Sectors 230 6.
7 Hydrogen in the Welding, Cement and Paper Industries 231 6.8 Hydrogen for Electricity Generation 231 6.9 Hydrogen in ICEs 233 6.10 ICEs 235 6.10.1 Anomalies in Hydrogen Combustion Systems: Pre-ignition and Backfire 236 6.10.2 Phenomenon of Backfire: Causes and Control Techniques 237 6.
11 Choice of Engine Configuration for Hydrogen Fuelling 241 6.12 Performance of a Hydrogen-Operated SI Engine 242 6.13 Exhaust Emission Characteristics of Hydrogen Engine and NOx Control 248 6.14 Exhaust Gas Recirculation 249 6.15 Spark Timing 250 6.16 Catalytic Methods 251 6.16.1 Use of Unburnt H2 251 6.
16.2 Dosing of External H2 252 6.17 Operation at a High Equivalence Ratio 253 6.18 Development of Hydrogen Engine (Both SI and CI Engine) Gensets 256 6.19 Combustion in Hydrogen-fuelled SI Engines 257 6.20 Significant Contribution of Laser Ignition to Engine Combustion 258 6.20.1 Laser Ignition 258 6.
20.2 Hydrogen-fuelled Laser-ignited Engine 260 6.21 Hydrogen Use in CI Engines 263 6.22 Use of Hydrogen in the Rotary (Wankel Engine) 266 6.23 Use of Hydrogen in ICEs with Natural Gas 267 6.24 Hydrogen in Combination with Other Fuels for ICEs 273 6.24.1 Hydrogen with Ethanol 273 6.
24.2 Hydrogen and DME 275 6.24.3 Hydrogen with Propane and LPG 276 6.24.4 Hydrogen Addition to Biogas-Biodiesel Engine 279 6.25 Homogeneous Charge Compression Ignition Engine (HCCI) 280 6.26 Hydrogen-fuelled Vehicles (ICE Based) 282 6.
27 Hydrogen in Fuel Cells 285 6.27.1 Types of Fuel Cells 287 6.27.2 Hydrogen Powertrains 293 6.27.3 Fuel Cell in the Transport Sector 294 6.27.
4 Fuel Cell Buses and Trucks 295 6.27.5 Off-road Transport Trains 296 6.27.6 Stationary Power 297 6.27.6 Hydrogen in Gas Turbines 299 6.27.
7 Hydrogen for Maritime Applications: Ships, Submarines and Boats 302 6.27.8 Hydrogen in Aviation and Air Transport 306 6.27.9 Hydrogen Use in the Domestic Sector 308 Concluding Remarks 310 Abbreviations 310 References 313 7 Life Cycle Sustainability Assessment, Durability and Material Compatibility 321 7.1 Introduction 321 7.2 Life Cycle Analysis 323 7.2.
1 Stages of Life Cycle Assessm.