Sustainable Energy: Choosing Among OptionsMIT Press, 2005 - 846 pages Human survival depends on a continuing energy supply, but the need for ever-increasing amounts of energy poses a dilemma: How can we provide the benefits of energy to the population of the globe without damaging the environment, negatively affecting social stability, or threatening the well-being of future generations? The solution will lie in finding sustainable energy sources and more efficient means of converting and utilizing energy. This textbook is designed for advanced undergraduate and graduate students as well as others who have an interest in exploring energy resource options and technologies with a view toward achieving sustainability. It clearly presents the trade-offs and uncertainties inherent in evaluating and choosing different energy options and provides a framework for assessing policy solutions. Sustainable Energy includes illustrative examples, problems, references for further reading, and links to relevant Web sites and can be used outside the classroom as a resource for government, industry, and nonprofit organizations. The first six chapters provide the tools for making informed energy choices. estimation, environmental effects, and economic evaluations. Chapters 7-15 review the main energy sources of today and tomorrow, including fossil fuels, nuclear power, biomass, geothermal energy, hydropower, wind energy, and solar energy, examining their technologies, environmental impacts, and economics. The remaining chapters treat energy storage, transmission, and distribution; the electric power sector; transportation; industrial energy usage; commercial and residential buildings; and synergistic complex systems. The book addresses the challenges of integrating diverse factors and the importance for future generations of the energy choices we make today. |
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Page v
... Analysis 3.2.1 Allowability , efficiency , and the Second Law 3.2.2 More about entropy • 88 90 90 92 3.2.3 Analysis of ideal ( Carnot ) heat engines 3.2.4.
... Analysis 3.2.1 Allowability , efficiency , and the Second Law 3.2.2 More about entropy • 88 90 90 92 3.2.3 Analysis of ideal ( Carnot ) heat engines 3.2.4.
Page vi
... Analysis of real world ( irreversible ) heat engines 3.3 The Importance of Rate Processes in Energy Conversion 3.4 Chemical Rate Processes 3.5 The Physical Transport of Heat 3.5.1 Foundations for quantitative analysis 3.5.2 Thermal ...
... Analysis of real world ( irreversible ) heat engines 3.3 The Importance of Rate Processes in Energy Conversion 3.4 Chemical Rate Processes 3.5 The Physical Transport of Heat 3.5.1 Foundations for quantitative analysis 3.5.2 Thermal ...
Page vii
... Analysis Approaches 259 · 260 263 . 271 6.3.1 Lifecycle analysis 6.3.2 Simulation models 6.3.3 Risk - based Contents vii.
... Analysis Approaches 259 · 260 263 . 271 6.3.1 Lifecycle analysis 6.3.2 Simulation models 6.3.3 Risk - based Contents vii.
Page viii
Choosing Among Options Jefferson W. Tester. 6.3.1 Lifecycle analysis 6.3.2 Simulation models 6.3.3 Risk - based models 6.4 Measures of Sustainability 6.4.1 General indicators of sustainability 6.4.2 Categories of indicators 6.5 Drivers ...
Choosing Among Options Jefferson W. Tester. 6.3.1 Lifecycle analysis 6.3.2 Simulation models 6.3.3 Risk - based models 6.4 Measures of Sustainability 6.4.1 General indicators of sustainability 6.4.2 Categories of indicators 6.5 Drivers ...
Page xv
... Analysis and Design for Sustainability 763 19.3 Metals Industries 766 19.4 Cement and Lime Industries 767 19.5 Chemical Industries . . 769 19.6 Forest Products and Agriculture 19.7 Waste Management Industries 19.8 Sustainability Issues ...
... Analysis and Design for Sustainability 763 19.3 Metals Industries 766 19.4 Cement and Lime Industries 767 19.5 Chemical Industries . . 769 19.6 Forest Products and Agriculture 19.7 Waste Management Industries 19.8 Sustainability Issues ...
Contents
Renewable Energy in Context | 9 |
References | 48 |
Allowability Efficiency Production Rates | 87 |
Local Regional and Global Environmental Effects of Energy | 137 |
Problems | 199 |
Appendix A | 245 |
Energy Systems and Sustainability Metrics | 259 |
References | 289 |
References | 585 |
607 | |
454 | 611 |
Wind Energy | 613 |
References | 640 |
Storage Transportation and Distribution of Energy | 647 |
Electric Power Sector | 693 |
724 | |
Fossil Fuels and Fossil Energy | 295 |
References | 355 |
Nuclear Power | 361 |
405 | |
References | 446 |
References | 453 |
Geothermal Energy | 454 |
References | 519 |
757 | |
References | 774 |
794 | |
819 | |
Conversion Factors | 827 |
837 | |
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analysis Assessment atmosphere atoms biomass Brayton cycle busbar capacity carbon Chapter chemical reaction climate change CO₂ coal combustion components conversion cooling cycle depletion earth economic ecosystems effects efficiency electric power energy technologies environment environmental impacts Equation estimates ethanol example factors Figure fission flow fluid fossil fuels fuel cell fusion future gases gasoline global greenhouse heat engine heat transfer Hubbert curves human hydrogen hydropower important increase industrial industrial ecology IPCC liquid major materials mechanisms mineral models nations natural gas needed neutrons nuclear fission nuclear power operating options oxidant particles petroleum pollutants potential power plant pressure production pump radiation Rankine cycle reactor reduce regions renewable energy reservoir scale solar energy steam storage supply surface sustainable development sustainable energy Table temperature thermal thermodynamic transport turbine typically unit uranium utilization vapor waste