Christian Ngo,
Ngo,
Joseph Natowitz
Our Energy Future – Resources, Alternatives and the Environment 2e
Resources, Alternatives and the Environment
Gebonden Engels 2016 9781119213369
Verwachte levertijd ongeveer 9 werkdagen
Samenvatting
Presents an overview on the different aspects of the energy value chain and discusses the issues that future energy is facing
This book covers energy and the energy policy choices which face society. The book presents easy–to–grasp information and analysis, and includes statistical data for energy production, consumption and simple formulas. Among the aspects considered are: science, technology, economics and the impact on health and the environment. In this new edition two new chapters have been added: The first new chapter deals with unconventional fossil fuels, a resource which has become very important from the economical point of view, especially in the United States. The second new chapter presents the applications of nanotechnology in the energy domain.
Provides a global vision of available and potential energy sources
Discusses advantages and drawbacks to help prepare current and future generations to use energy differently
Includes new chapters covering unconventional fossil fuels and nanotechnology as new energy
Our Energy Future: Resources, Alternatives and the Environment, Second Edition, is written for professionals, students, teachers, decision–makers and politicians involved in the energy domain and interested in environmental issues.
Specificaties
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Inhoudsopgave
<p>Preface to the Second Edition xiii</p>
<p>Preface to the First Edition xv</p>
<p>1. We Need Energy 1</p>
<p>1.1. Generalities 1</p>
<p>1.1.1. Primary and Secondary Energy 1</p>
<p>1.1.2. Energy Units 3</p>
<p>1.1.3. Power 5</p>
<p>1.1.4. Energy and First Law of Thermodynamics 5</p>
<p>1.1.5. Entropy and Second Law of Thermodynamics 6</p>
<p>1.1.6. Exergy 7</p>
<p>1.1.7. Going Back to the Past 7</p>
<p>1.1.8. Humans and Energy 8</p>
<p>1.2. Always More! 9</p>
<p>1.2.1. Why do we Need More Energy? 10</p>
<p>1.2.2. Energy Sources we Use 13</p>
<p>1.2.3. Security of Supply 18</p>
<p>1.2.4. Environmental Concerns 24</p>
<p>2. Oil and Natural Gas 26</p>
<p>2.1. Genesis of Oil and Natural Gas 27</p>
<p>2.2. Recovering Oil and Gas 30</p>
<p>2.3. Peak Oil 32</p>
<p>2.4. Reserves 34</p>
<p>2.4.1. Crude Oil Reserves 35</p>
<p>2.4.2. Natural Gas Reserves 36</p>
<p>2.5. Properties of Hydrocarbons 38</p>
<p>2.6. Oil Fields 40</p>
<p>2.7. Prices 41</p>
<p>2.8. Consumption 44</p>
<p>2.9. Electricity Generation 46</p>
<p>2.10. Impact on Environment 49</p>
<p>2.11. Conclusion 52</p>
<p>3. Unconventional Oil and Gas Resources 53</p>
<p>3.1. Hydrocarbon Formation 53</p>
<p>3.2. Offshore Hydrocarbons 55</p>
<p>3.3. Unconventional Hydrocarbons 58</p>
<p>3.4. Unconventional Oils 59</p>
<p>3.4.1. Unconventional Oils Contained in Reservoirs 59</p>
<p>3.4.2. Unconventional Oils Contained in Source Rock 60</p>
<p>3.5. Unconventional Gases 61</p>
<p>3.5.1. Unconventional Gases Contained in Reservoirs 61</p>
<p>3.5.2. Unconventional Gases Contained in Source Rocks 62</p>
<p>3.6. Methane Hydrates 69</p>
<p>3.7. Conclusion 70</p>
<p>4. Coal: Fossil Fuel of the Future 71</p>
<p>4.1. Genesis of Coal 72</p>
<p>4.2. Rank of Coals 73</p>
<p>4.3. Classification of Coals 73</p>
<p>4.4. Peat 76</p>
<p>4.5. Use of Coal 78</p>
<p>4.6. Coal Reserves 78</p>
<p>4.7. Production and Consumption 82</p>
<p>4.8. Electricity Production 86</p>
<p>4.9. Coal Combustion for Power Generation 87</p>
<p>4.9.1. Advanced Pulverized Coal Combustion 88</p>
<p>4.9.2. Fluidized ]Bed Combustion at Atmospheric Pressure 88</p>
<p>4.9.3. Pressurized Fluidized ]Bed Combustion 88</p>
<p>4.10. Combined Heat and Power Generation 88</p>
<p>4.11. Integrated Gasification Combined Cycle Power Plants 89</p>
<p>4.12. Coal ]to ]Liquid Technologies 90</p>
<p>4.13. Direct Coal Liquefaction 90</p>
<p>4.14. Indirect Coal Liquefaction 91</p>
<p>4.15. Direct or Indirect CTL Technology? 92</p>
<p>4.16. Carbon Capture and Sequestration 93</p>
<p>4.16.1. Capture 93</p>
<p>4.16.2. Transport 97</p>
<p>4.16.3. Sequestration 97</p>
<p>4.16.4. Cost 100</p>
<p>4.17. Coal Pit Accidents 100</p>
<p>4.18. Environmental Impacts 101</p>
<p>4.19. Conclusion 102</p>
<p>5. Fossil Fuels and Greenhouse Effect 103</p>
<p>5.1. Greenhouse Effect 104</p>
<p>5.2. Greenhouse Gases 107</p>
<p>5.3. Weather and Climate 111</p>
<p>5.4. Natural Change of Climate 112</p>
<p>5.5. Anthropogenic Emissions 112</p>
<p>5.6. Water and Aerosols 115</p>
<p>5.7. Global Warming Potentials 116</p>
<p>5.8. Increase of Average Temperature 117</p>
<p>5.9. Model Predictions 118</p>
<p>5.10. Energy and Greenhouse Gas Emissions 119</p>
<p>5.11. Consequences 126</p>
<p>5.12. Other Impacts on Ocean 126</p>
<p>5.13. Factor 4 128</p>
<p>5.14. Kyoto Protocol 129</p>
<p>5.15. Conclusion 131</p>
<p>6. Energy from Water 133</p>
<p>6.1. Hydropower 133</p>
<p>6.1.1. Hydropower: Important Source of Electricity 134</p>
<p>6.1.2. Dams and Diversions 137</p>
<p>6.1.3. Head and Flow 139</p>
<p>6.1.4. Turbines 140</p>
<p>6.1.5. Small ]Scale Hydropower 142</p>
<p>6.1.6. Environmental Concerns 144</p>
<p>6.1.7. Costs 144</p>
<p>6.2. Energy from the Ocean 145</p>
<p>6.2.1. Offshore Wind Energy 147</p>
<p>6.2.2. Wave Energy 147</p>
<p>6.2.3. Tidal Energy 151</p>
<p>6.2.4. Marine Current Energy 153</p>
<p>6.2.5. Ocean Thermal Energy Conversion 154</p>
<p>6.2.6. Osmotic Energy 155</p>
<p>7. Biomass 157</p>
<p>7.1. Producing Biomass 159</p>
<p>7.2. An Old Energy Resource 161</p>
<p>7.3. Electricity Production 162</p>
<p>7.4. Technologies 164</p>
<p>7.4.1. Direct Combustion Technologies 164</p>
<p>7.4.2. Cofiring Technologies 165</p>
<p>7.4.3. Biomass Gasification 165</p>
<p>7.4.4. Anaerobic Digestion 166</p>
<p>7.4.5. Pyrolysis 166</p>
<p>7.5. Heat Production 167</p>
<p>7.6. Biomass for Cooking 168</p>
<p>7.7. Environmental Impact 169</p>
<p>7.8. Market Share 170</p>
<p>7.9. Biofuels 172</p>
<p>7.9.1. First ]Generation Biofuels 174</p>
<p>7.9.2. Second ]Generation Biofuels 181</p>
<p>7.9.3. Third ]Generation Biofuels 182</p>
<p>7.10. From Well to Wheels 182</p>
<p>7.11. Conclusion 183</p>
<p>8. Solar Energy 184</p>
<p>8.1. Solar Energy: A Huge Potential 185</p>
<p>8.2. Thermal Solar Energy 186</p>
<p>8.2.1. Producing Hot Water for Domestic Purposes 186</p>
<p>8.2.2. Heating, Cooling, and Ventilation Using Solar Energy 189</p>
<p>8.2.3. The Solar Cooker 190</p>
<p>8.3. Concentrated Solar Power Plants 191</p>
<p>8.3.1. Parabolic Troughs 191</p>
<p>8.3.2. Power Towers 193</p>
<p>8.3.3. Parabolic Dish Collectors 194</p>
<p>8.4. Solar Chimneys or Towers 194</p>
<p>8.5. Photovoltaic Systems 196</p>
<p>8.5.1. Market Dominated by Silicon 197</p>
<p>8.5.2. Other Photovoltaic Technologies 198</p>
<p>8.5.3. Applications 199</p>
<p>8.6. Electricity Storage 204</p>
<p>8.7. Economy and Environment 205</p>
<p>8.8. Conclusion 205</p>
<p>9. Geothermal Energy 207</p>
<p>9.1. Available in Many Places 210</p>
<p>9.2. Different Uses 212</p>
<p>9.3. Technologies 212</p>
<p>9.4. Geothermal Energy in the World 216</p>
<p>9.5. Conclusion 219</p>
<p>10. Wind Energy 220</p>
<p>10.1. Already A Long History 220</p>
<p>10.2. From Theory to Practice 222</p>
<p>10.3. Development of Wind Power 224</p>
<p>10.4. Offshore Wind Turbines 232</p>
<p>10.5. Conclusion 233</p>
<p>11. Nuclear Energy 234</p>
<p>11.1. Basics of Nuclear Energy 234</p>
<p>11.1.1. Atoms and Nuclei 235</p>
<p>11.1.2. Radioactivity 236</p>
<p>11.1.3. Energy and Mass 238</p>
<p>11.1.4. Fission 240</p>
<p>11.1.5. Fissile and Fertile 241</p>
<p>11.1.6. Chain Reaction 242</p>
<p>11.1.7. Critical Mass 244</p>
<p>11.1.8. Nuclear Reactors 245</p>
<p>11.1.9. Natural Nuclear Reactors: Oklo 246</p>
<p>11.1.10. Conclusion 247</p>
<p>11.2. Uses of Nuclear Energy 247</p>
<p>11.2.1. Different Technologies 248</p>
<p>11.2.2. Selection Process 251</p>
<p>11.2.3. Why Nuclear Energy? 253</p>
<p>11.2.4. Uranium Resources 254</p>
<p>11.2.5. Fuel Cycles 257</p>
<p>11.2.6. Safety 260</p>
<p>11.2.7. Nuclear Waste 263</p>
<p>11.2.8. Conclusion 265</p>
<p>11.3. Thermonuclear Fusion 266</p>
<p>11.3.1. Nuclei: Concentrated Sources of Energy 266</p>
<p>11.3.2. The Sun 267</p>
<p>11.3.3. Fusion of Light Nuclei 268</p>
<p>11.3.4. Difficulties 268</p>
<p>11.3.5. A Bit of History 269</p>
<p>11.3.6. Thermonuclear Fusion in Tokamaks 269</p>
<p>11.3.7. ITER: New Step Toward Mastering Fusion 270</p>
<p>11.3.8. About Fuel Reserves 271</p>
<p>11.3.9. Longer Term Possibilities 271</p>
<p>11.3.10. Safety and Waste Issues 272</p>
<p>11.3.11. Conclusion 272</p>
<p>Appendix 273</p>
<p>12. Electricity: Smart Use of Energy 274</p>
<p>12.1. Rapid Development 275</p>
<p>12.2. Energy Sources for Electricity Production 279</p>
<p>12.3. No Unique Solution 281</p>
<p>12.4. From Mechanical Energy to Consumer 286</p>
<p>12.5. Impact on Environment 288</p>
<p>12.6. Cost 289</p>
<p>12.7. Conclusion 290</p>
<p>13. Weak Point of Energy Supply Chain 292</p>
<p>13.1. Electricity Storage 294</p>
<p>13.1.1. Characteristics of Electricity Storage 296</p>
<p>13.1.2. Large ]Quantity Storage Technologies 297</p>
<p>13.1.3. Electrochemical Batteries 303</p>
<p>13.1.4. Supercapacitors 315</p>
<p>13.1.5. Flywheels 317</p>
<p>13.2. Thermal Energy Storage 318</p>
<p>13.2.1. Basic Heat Storage 320</p>
<p>13.2.2. Sensible Heat Storage 320</p>
<p>13.2.3. Phase Change Materials 320</p>
<p>13.2.4. Thermochemical and Thermophysical Energy Storage 322</p>
<p>13.2.5. Applications of Thermal Energy Storage 323</p>
<p>13.2.6. Underground Energy Storage 324</p>
<p>13.2.7. Conclusion 326</p>
<p>14. Transportation 327</p>
<p>14.1. Short History of Transportation 327</p>
<p>14.2. Energy and Transportation 329</p>
<p>14.3. Road Transportation 331</p>
<p>14.4. Ship Transportation 336</p>
<p>14.5. Air Transport 337</p>
<p>14.6. Car Dynamics 339</p>
<p>14.7. Fuels for Road Transportation 340</p>
<p>14.8. Co2 Emissions 343</p>
<p>14.9. Hybrid Vehicles 354</p>
<p>14.10. Electric Vehicles 356</p>
<p>14.11. Conclusion 358</p>
<p>15. Housing 359</p>
<p>15.1. Importance of Housing 359</p>
<p>15.2. Toward More Efficient Housing 363</p>
<p>15.3. Different Regions, Different Solutions 367</p>
<p>15.4. Bioclimatic Architecture 369</p>
<p>15.5. Insulation 370</p>
<p>15.6. Glazing 374</p>
<p>15.7. Lighting 376</p>
<p>15.8. Ventilation 379</p>
<p>15.9. Water 380</p>
<p>15.10. Energy Use in a Household 382</p>
<p>15.11. Heat Pumps 384</p>
<p>15.12. Impact on Environment 387</p>
<p>15.13. Conclusion 390</p>
<p>16. Smart Energy Consumption 391</p>
<p>16.1. Housing 392</p>
<p>16.2. Improving the Way we Consume Energy 393</p>
<p>16.3. Cogeneration 394</p>
<p>16.4. Standby Consumption 396</p>
<p>16.5. Lighting 401</p>
<p>16.6. Transportation 402</p>
<p>16.6.1. Technology 404</p>
<p>16.6.2. Individuals 405</p>
<p>16.7. Conclusion 407</p>
<p>17. Hydrogen 409</p>
<p>17.1. From Production To Distribution 409</p>
<p>17.1.1. Properties 409</p>
<p>17.1.2. Production 411</p>
<p>17.1.3. Storage 420</p>
<p>17.1.4. Hydrogen Transport and Distribution 425</p>
<p>17.1.5. Conclusion 428</p>
<p>17.2. Hydrogen: Energetic Applications 428</p>
<p>17.2.1. Fundamentals of Fuel Cells 428</p>
<p>17.2.2. Different Types of Fuel Cells 431</p>
<p>17.2.3. Transportation 439</p>
<p>17.2.4. Direct Use of Hydrogen 446</p>
<p>17.2.5. Direct Combined Heat and Power 447</p>
<p>17.2.6. Hydrogen and Portable Devices 448</p>
<p>17.2.7. Hydrogen Safety 449</p>
<p>17.2.8. Conclusion 450</p>
<p>18. Nanotechnology and Energy 452</p>
<p>18.1. What is New at the Nanoscale? 452</p>
<p>18.1.1. Surface Effects Prevail 453</p>
<p>18.1.2. Quantum Effects 453</p>
<p>18.2. Nanotechnology and Energy Production 456</p>
<p>18.2.1. Fossil Fuels 457</p>
<p>18.2.2. Syngas 458</p>
<p>18.3. New Energy Technologies 459</p>
<p>18.3.1. Solar Energy 460</p>
<p>18.3.2. Wind Energy 462</p>
<p>18.3.3. Hydrogen 462</p>
<p>18.3.4. Fuel Cells 462</p>
<p>18.3.5. Batteries 463</p>
<p>18.3.6. Thermoelectricity 464</p>
<p>18.3.7. Electrical Distribution 464</p>
<p>18.4. Nanotechnology and Housing 464</p>
<p>18.4.1. Construction Engineering 464</p>
<p>18.4.2. Insulation 465</p>
<p>18.4.3. Lighting 466</p>
<p>18.4.4. Heating, Ventilating, and Air ]Conditioning 468</p>
<p>18.4.5. Surface Materials 468</p>
<p>18.5. Nanotechnology and Transportation 468</p>
<p>18.5.1. Bodywork 469</p>
<p>18.5.2. Interior of the Car 470</p>
<p>18.5.3. Tires 470</p>
<p>18.5.4. Powertrain 471</p>
<p>18.5.5. Electronics 471</p>
<p>18.5.6. Outlook in the Automotive Sector 471</p>
<p>18.6. Conclusion 472</p>
<p>19. Conclusion 474</p>
<p>Exercises 480</p>
<p>Solutions 490</p>
<p>Bibliography 500</p>
<p>Index 505</p>
<p>Preface to the First Edition xv</p>
<p>1. We Need Energy 1</p>
<p>1.1. Generalities 1</p>
<p>1.1.1. Primary and Secondary Energy 1</p>
<p>1.1.2. Energy Units 3</p>
<p>1.1.3. Power 5</p>
<p>1.1.4. Energy and First Law of Thermodynamics 5</p>
<p>1.1.5. Entropy and Second Law of Thermodynamics 6</p>
<p>1.1.6. Exergy 7</p>
<p>1.1.7. Going Back to the Past 7</p>
<p>1.1.8. Humans and Energy 8</p>
<p>1.2. Always More! 9</p>
<p>1.2.1. Why do we Need More Energy? 10</p>
<p>1.2.2. Energy Sources we Use 13</p>
<p>1.2.3. Security of Supply 18</p>
<p>1.2.4. Environmental Concerns 24</p>
<p>2. Oil and Natural Gas 26</p>
<p>2.1. Genesis of Oil and Natural Gas 27</p>
<p>2.2. Recovering Oil and Gas 30</p>
<p>2.3. Peak Oil 32</p>
<p>2.4. Reserves 34</p>
<p>2.4.1. Crude Oil Reserves 35</p>
<p>2.4.2. Natural Gas Reserves 36</p>
<p>2.5. Properties of Hydrocarbons 38</p>
<p>2.6. Oil Fields 40</p>
<p>2.7. Prices 41</p>
<p>2.8. Consumption 44</p>
<p>2.9. Electricity Generation 46</p>
<p>2.10. Impact on Environment 49</p>
<p>2.11. Conclusion 52</p>
<p>3. Unconventional Oil and Gas Resources 53</p>
<p>3.1. Hydrocarbon Formation 53</p>
<p>3.2. Offshore Hydrocarbons 55</p>
<p>3.3. Unconventional Hydrocarbons 58</p>
<p>3.4. Unconventional Oils 59</p>
<p>3.4.1. Unconventional Oils Contained in Reservoirs 59</p>
<p>3.4.2. Unconventional Oils Contained in Source Rock 60</p>
<p>3.5. Unconventional Gases 61</p>
<p>3.5.1. Unconventional Gases Contained in Reservoirs 61</p>
<p>3.5.2. Unconventional Gases Contained in Source Rocks 62</p>
<p>3.6. Methane Hydrates 69</p>
<p>3.7. Conclusion 70</p>
<p>4. Coal: Fossil Fuel of the Future 71</p>
<p>4.1. Genesis of Coal 72</p>
<p>4.2. Rank of Coals 73</p>
<p>4.3. Classification of Coals 73</p>
<p>4.4. Peat 76</p>
<p>4.5. Use of Coal 78</p>
<p>4.6. Coal Reserves 78</p>
<p>4.7. Production and Consumption 82</p>
<p>4.8. Electricity Production 86</p>
<p>4.9. Coal Combustion for Power Generation 87</p>
<p>4.9.1. Advanced Pulverized Coal Combustion 88</p>
<p>4.9.2. Fluidized ]Bed Combustion at Atmospheric Pressure 88</p>
<p>4.9.3. Pressurized Fluidized ]Bed Combustion 88</p>
<p>4.10. Combined Heat and Power Generation 88</p>
<p>4.11. Integrated Gasification Combined Cycle Power Plants 89</p>
<p>4.12. Coal ]to ]Liquid Technologies 90</p>
<p>4.13. Direct Coal Liquefaction 90</p>
<p>4.14. Indirect Coal Liquefaction 91</p>
<p>4.15. Direct or Indirect CTL Technology? 92</p>
<p>4.16. Carbon Capture and Sequestration 93</p>
<p>4.16.1. Capture 93</p>
<p>4.16.2. Transport 97</p>
<p>4.16.3. Sequestration 97</p>
<p>4.16.4. Cost 100</p>
<p>4.17. Coal Pit Accidents 100</p>
<p>4.18. Environmental Impacts 101</p>
<p>4.19. Conclusion 102</p>
<p>5. Fossil Fuels and Greenhouse Effect 103</p>
<p>5.1. Greenhouse Effect 104</p>
<p>5.2. Greenhouse Gases 107</p>
<p>5.3. Weather and Climate 111</p>
<p>5.4. Natural Change of Climate 112</p>
<p>5.5. Anthropogenic Emissions 112</p>
<p>5.6. Water and Aerosols 115</p>
<p>5.7. Global Warming Potentials 116</p>
<p>5.8. Increase of Average Temperature 117</p>
<p>5.9. Model Predictions 118</p>
<p>5.10. Energy and Greenhouse Gas Emissions 119</p>
<p>5.11. Consequences 126</p>
<p>5.12. Other Impacts on Ocean 126</p>
<p>5.13. Factor 4 128</p>
<p>5.14. Kyoto Protocol 129</p>
<p>5.15. Conclusion 131</p>
<p>6. Energy from Water 133</p>
<p>6.1. Hydropower 133</p>
<p>6.1.1. Hydropower: Important Source of Electricity 134</p>
<p>6.1.2. Dams and Diversions 137</p>
<p>6.1.3. Head and Flow 139</p>
<p>6.1.4. Turbines 140</p>
<p>6.1.5. Small ]Scale Hydropower 142</p>
<p>6.1.6. Environmental Concerns 144</p>
<p>6.1.7. Costs 144</p>
<p>6.2. Energy from the Ocean 145</p>
<p>6.2.1. Offshore Wind Energy 147</p>
<p>6.2.2. Wave Energy 147</p>
<p>6.2.3. Tidal Energy 151</p>
<p>6.2.4. Marine Current Energy 153</p>
<p>6.2.5. Ocean Thermal Energy Conversion 154</p>
<p>6.2.6. Osmotic Energy 155</p>
<p>7. Biomass 157</p>
<p>7.1. Producing Biomass 159</p>
<p>7.2. An Old Energy Resource 161</p>
<p>7.3. Electricity Production 162</p>
<p>7.4. Technologies 164</p>
<p>7.4.1. Direct Combustion Technologies 164</p>
<p>7.4.2. Cofiring Technologies 165</p>
<p>7.4.3. Biomass Gasification 165</p>
<p>7.4.4. Anaerobic Digestion 166</p>
<p>7.4.5. Pyrolysis 166</p>
<p>7.5. Heat Production 167</p>
<p>7.6. Biomass for Cooking 168</p>
<p>7.7. Environmental Impact 169</p>
<p>7.8. Market Share 170</p>
<p>7.9. Biofuels 172</p>
<p>7.9.1. First ]Generation Biofuels 174</p>
<p>7.9.2. Second ]Generation Biofuels 181</p>
<p>7.9.3. Third ]Generation Biofuels 182</p>
<p>7.10. From Well to Wheels 182</p>
<p>7.11. Conclusion 183</p>
<p>8. Solar Energy 184</p>
<p>8.1. Solar Energy: A Huge Potential 185</p>
<p>8.2. Thermal Solar Energy 186</p>
<p>8.2.1. Producing Hot Water for Domestic Purposes 186</p>
<p>8.2.2. Heating, Cooling, and Ventilation Using Solar Energy 189</p>
<p>8.2.3. The Solar Cooker 190</p>
<p>8.3. Concentrated Solar Power Plants 191</p>
<p>8.3.1. Parabolic Troughs 191</p>
<p>8.3.2. Power Towers 193</p>
<p>8.3.3. Parabolic Dish Collectors 194</p>
<p>8.4. Solar Chimneys or Towers 194</p>
<p>8.5. Photovoltaic Systems 196</p>
<p>8.5.1. Market Dominated by Silicon 197</p>
<p>8.5.2. Other Photovoltaic Technologies 198</p>
<p>8.5.3. Applications 199</p>
<p>8.6. Electricity Storage 204</p>
<p>8.7. Economy and Environment 205</p>
<p>8.8. Conclusion 205</p>
<p>9. Geothermal Energy 207</p>
<p>9.1. Available in Many Places 210</p>
<p>9.2. Different Uses 212</p>
<p>9.3. Technologies 212</p>
<p>9.4. Geothermal Energy in the World 216</p>
<p>9.5. Conclusion 219</p>
<p>10. Wind Energy 220</p>
<p>10.1. Already A Long History 220</p>
<p>10.2. From Theory to Practice 222</p>
<p>10.3. Development of Wind Power 224</p>
<p>10.4. Offshore Wind Turbines 232</p>
<p>10.5. Conclusion 233</p>
<p>11. Nuclear Energy 234</p>
<p>11.1. Basics of Nuclear Energy 234</p>
<p>11.1.1. Atoms and Nuclei 235</p>
<p>11.1.2. Radioactivity 236</p>
<p>11.1.3. Energy and Mass 238</p>
<p>11.1.4. Fission 240</p>
<p>11.1.5. Fissile and Fertile 241</p>
<p>11.1.6. Chain Reaction 242</p>
<p>11.1.7. Critical Mass 244</p>
<p>11.1.8. Nuclear Reactors 245</p>
<p>11.1.9. Natural Nuclear Reactors: Oklo 246</p>
<p>11.1.10. Conclusion 247</p>
<p>11.2. Uses of Nuclear Energy 247</p>
<p>11.2.1. Different Technologies 248</p>
<p>11.2.2. Selection Process 251</p>
<p>11.2.3. Why Nuclear Energy? 253</p>
<p>11.2.4. Uranium Resources 254</p>
<p>11.2.5. Fuel Cycles 257</p>
<p>11.2.6. Safety 260</p>
<p>11.2.7. Nuclear Waste 263</p>
<p>11.2.8. Conclusion 265</p>
<p>11.3. Thermonuclear Fusion 266</p>
<p>11.3.1. Nuclei: Concentrated Sources of Energy 266</p>
<p>11.3.2. The Sun 267</p>
<p>11.3.3. Fusion of Light Nuclei 268</p>
<p>11.3.4. Difficulties 268</p>
<p>11.3.5. A Bit of History 269</p>
<p>11.3.6. Thermonuclear Fusion in Tokamaks 269</p>
<p>11.3.7. ITER: New Step Toward Mastering Fusion 270</p>
<p>11.3.8. About Fuel Reserves 271</p>
<p>11.3.9. Longer Term Possibilities 271</p>
<p>11.3.10. Safety and Waste Issues 272</p>
<p>11.3.11. Conclusion 272</p>
<p>Appendix 273</p>
<p>12. Electricity: Smart Use of Energy 274</p>
<p>12.1. Rapid Development 275</p>
<p>12.2. Energy Sources for Electricity Production 279</p>
<p>12.3. No Unique Solution 281</p>
<p>12.4. From Mechanical Energy to Consumer 286</p>
<p>12.5. Impact on Environment 288</p>
<p>12.6. Cost 289</p>
<p>12.7. Conclusion 290</p>
<p>13. Weak Point of Energy Supply Chain 292</p>
<p>13.1. Electricity Storage 294</p>
<p>13.1.1. Characteristics of Electricity Storage 296</p>
<p>13.1.2. Large ]Quantity Storage Technologies 297</p>
<p>13.1.3. Electrochemical Batteries 303</p>
<p>13.1.4. Supercapacitors 315</p>
<p>13.1.5. Flywheels 317</p>
<p>13.2. Thermal Energy Storage 318</p>
<p>13.2.1. Basic Heat Storage 320</p>
<p>13.2.2. Sensible Heat Storage 320</p>
<p>13.2.3. Phase Change Materials 320</p>
<p>13.2.4. Thermochemical and Thermophysical Energy Storage 322</p>
<p>13.2.5. Applications of Thermal Energy Storage 323</p>
<p>13.2.6. Underground Energy Storage 324</p>
<p>13.2.7. Conclusion 326</p>
<p>14. Transportation 327</p>
<p>14.1. Short History of Transportation 327</p>
<p>14.2. Energy and Transportation 329</p>
<p>14.3. Road Transportation 331</p>
<p>14.4. Ship Transportation 336</p>
<p>14.5. Air Transport 337</p>
<p>14.6. Car Dynamics 339</p>
<p>14.7. Fuels for Road Transportation 340</p>
<p>14.8. Co2 Emissions 343</p>
<p>14.9. Hybrid Vehicles 354</p>
<p>14.10. Electric Vehicles 356</p>
<p>14.11. Conclusion 358</p>
<p>15. Housing 359</p>
<p>15.1. Importance of Housing 359</p>
<p>15.2. Toward More Efficient Housing 363</p>
<p>15.3. Different Regions, Different Solutions 367</p>
<p>15.4. Bioclimatic Architecture 369</p>
<p>15.5. Insulation 370</p>
<p>15.6. Glazing 374</p>
<p>15.7. Lighting 376</p>
<p>15.8. Ventilation 379</p>
<p>15.9. Water 380</p>
<p>15.10. Energy Use in a Household 382</p>
<p>15.11. Heat Pumps 384</p>
<p>15.12. Impact on Environment 387</p>
<p>15.13. Conclusion 390</p>
<p>16. Smart Energy Consumption 391</p>
<p>16.1. Housing 392</p>
<p>16.2. Improving the Way we Consume Energy 393</p>
<p>16.3. Cogeneration 394</p>
<p>16.4. Standby Consumption 396</p>
<p>16.5. Lighting 401</p>
<p>16.6. Transportation 402</p>
<p>16.6.1. Technology 404</p>
<p>16.6.2. Individuals 405</p>
<p>16.7. Conclusion 407</p>
<p>17. Hydrogen 409</p>
<p>17.1. From Production To Distribution 409</p>
<p>17.1.1. Properties 409</p>
<p>17.1.2. Production 411</p>
<p>17.1.3. Storage 420</p>
<p>17.1.4. Hydrogen Transport and Distribution 425</p>
<p>17.1.5. Conclusion 428</p>
<p>17.2. Hydrogen: Energetic Applications 428</p>
<p>17.2.1. Fundamentals of Fuel Cells 428</p>
<p>17.2.2. Different Types of Fuel Cells 431</p>
<p>17.2.3. Transportation 439</p>
<p>17.2.4. Direct Use of Hydrogen 446</p>
<p>17.2.5. Direct Combined Heat and Power 447</p>
<p>17.2.6. Hydrogen and Portable Devices 448</p>
<p>17.2.7. Hydrogen Safety 449</p>
<p>17.2.8. Conclusion 450</p>
<p>18. Nanotechnology and Energy 452</p>
<p>18.1. What is New at the Nanoscale? 452</p>
<p>18.1.1. Surface Effects Prevail 453</p>
<p>18.1.2. Quantum Effects 453</p>
<p>18.2. Nanotechnology and Energy Production 456</p>
<p>18.2.1. Fossil Fuels 457</p>
<p>18.2.2. Syngas 458</p>
<p>18.3. New Energy Technologies 459</p>
<p>18.3.1. Solar Energy 460</p>
<p>18.3.2. Wind Energy 462</p>
<p>18.3.3. Hydrogen 462</p>
<p>18.3.4. Fuel Cells 462</p>
<p>18.3.5. Batteries 463</p>
<p>18.3.6. Thermoelectricity 464</p>
<p>18.3.7. Electrical Distribution 464</p>
<p>18.4. Nanotechnology and Housing 464</p>
<p>18.4.1. Construction Engineering 464</p>
<p>18.4.2. Insulation 465</p>
<p>18.4.3. Lighting 466</p>
<p>18.4.4. Heating, Ventilating, and Air ]Conditioning 468</p>
<p>18.4.5. Surface Materials 468</p>
<p>18.5. Nanotechnology and Transportation 468</p>
<p>18.5.1. Bodywork 469</p>
<p>18.5.2. Interior of the Car 470</p>
<p>18.5.3. Tires 470</p>
<p>18.5.4. Powertrain 471</p>
<p>18.5.5. Electronics 471</p>
<p>18.5.6. Outlook in the Automotive Sector 471</p>
<p>18.6. Conclusion 472</p>
<p>19. Conclusion 474</p>
<p>Exercises 480</p>
<p>Solutions 490</p>
<p>Bibliography 500</p>
<p>Index 505</p>
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