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"The economist Julian Simon once called energy the 'master resource.' With this marvelously erudite, wonderfully detailed book, Vaclav Smil once again shows that when it comes to insightful discussions of the myriad complexities and consternations of the master resource, he is, without question, the master." --Robert Bryce, energy journalist and managing editor of Energy Tribune "Vaclav Smil's appreciation of energy systems combines Thomas Edison and Franz Kafka. He celebrates innovation and progress but also vividly shows the strange fates and fall-out of what appear to be some of humanity's best machines."--Jesse H. Ausubel, Director, Program for the Human Environment, The Rockefeller University -- Jesse H. Ausubel " Energy in Nature and Society is filled with facts, measurements, and brief but accurate descriptions of dozens of techniques, which when combined, force facts to make sense." Alfred W. Crosby BioScience " Energy in Nature and Society is unique in its value and its comprehensive coverage of all energy matters; it should be on the bookshelves of all professionals in science, social science, economics, and history." T.L.T. Grose CHOICE "Vaclav Smil"s appreciation of energy systems combines Thomas Edison and Franz Kafka. He celebrates innovation and progress but also vividly shows the strange fates and fall-out of what appear to be some of humanity"s best machines."Jesse H. Ausubel , Director, Program for the Human Environment, The Rockefeller University
Kurzbeschreibung
Energy in Nature and Society is a systematic and exhaustive analysis of all the major energy sources, storages, flows, and conversions that have shaped the evolution of the biosphere and civilization. Vaclav Smil uses fundamental unifying metrics (most notably for power density and energy intensity) to provide an integrated framework for analyzing all segments of energetics (the study of energy flows and their transformations). The book explores not only planetary energetics (such as solar radiation and geomorphic processes) and bioenergetics (photosynthesis, for example) but also human energetics (such as metabolism and thermoregulation), tracing them from hunter-gatherer and agricultural societies through modern-day industrial civilization. Included are chapters on heterotrophic conversions, traditional agriculture, preindustrial complexification, fossil fuels, fossil-fueled civilization, the energetics of food, and the implications of energetics for the environment. The book concludes with an examination of general patterns, trends, and socioeconomic considerations of energy use today, looking at correlations between energy and value, energy and the economy, energy and quality of life, and energy futures. Throughout the book, Smil chooses to emphasize the complexities and peculiarities of the real world, and the counterintuitive outcomes of many of its processes, over abstract models. Energy in Nature and Society provides a unique, comprehensive, single-volume analysis and reference source on all important energy matters, from natural to industrial energy flows, from fuels to food, from the Earth's formation to possible energy futures, and can serve as a text for courses in energy studies, global ecology, earth systems science, biology, and chemistry. Vaclav Smil is Distinguished Professor at the University of Manitoba and the author of many books, including Energy at the Crossroads (2003), The Earth's Biosphere: Evolution, Dynamics, and Change (2002), and Energies: An Illustrated Guide to the Biosphere and Civilization (1998), all of which are published by The MIT Press.
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Essential Encyclopedia
26. Mai 2009
Format:Taschenbuch|Von Amazon bestätigter Kauf
I bought the book "blind", since MIT Press have not enabled "Look Inside". If you are in two minds about the book, here is the Table of Contents to help you make up your mind:
1. The Universal Link: Energetics, Energy, and Power
1.1 Evolution of Energetics: From Aristotle to Einstein
1.2 Approaches to Understanding: Concepts, Variables, Units
2. Planetary Energetics: Atmosphere, Hydrosphere, Lithosphere
2.1 Sun: The Star and Its Radiation
2.2 Energy Balance of the Earth: Radiation Fluxes
2.3 Hydrophere and Atmosphere: thermal and Mass Fluxes
2.4 Water and Air in Motion: Kinetic Fluxes
2.5 Geoenergetics: Heat, Plate Tectonics, Volcanoes, Earthquakes
3. Photosynthesis: Bioenergetics of Primary Production
3.1 Photosynthetic Pathways
3.2 Global Primary Productivity
3.3 Productivities of Ecosystems and Plants
3.4 Phytomass Stores
3.5 Autotrophic Scaling
4. Heterotrophic Conversions: Consumer Bioenergetics
4.1 Metabolic Capacities
4.2 Ectotherms and Endotherms
4.3 Locomotion
4.4 Biomasses and Productivities
4.5 Heterotrophs in Ecosystems
5. Human Energetics: People as Simple Heterotrophs
5.1 Energy Sources and Basal Metabolism
5.2 Requirements and Uncertainties
5.3 Thermoregulation
5.4 Limits of Human Performance
5.5 Gathering, Hunting, and Fishing
6. Traditional Food Production: Humans as Solar Farmers
6.1 Extensive Practices
6.2 Permanent Cropping
6.3 Muscles, Implements, Machines
6.4 Cropping Intensification
6.5 Traditional Agricultures
7. Preindustrial Complexification: Prime Movers and Fuels in Traditional Societies
7.1 Animal Power: Human and Animal Muscles
7.2 Water and Wind: Wheels and Mills
7.3 Phytomass Fuels and Metallurgy: Wood, Charcoal, Crop Residues
7.4 Construction: Methods and Structures
7.5 Transportation: Roads and Ships
8. Fossil Fuels: Heat, Light, and Prime Movers
8.1 Coals: The Earliest Modern Fuels
8.2 Hydrocarbons: Crude Oils and Natural Gases
8.3 From Extraction to Combustion: Modern Fossil Fuel Industries
8.4 Mechanical Prime Movers: Engines and Turbines
8.5 Fossil-Fueled Electricity: Generation and Transmission
9. Fossil-Fueled Civilization: Patterns and Trends
9.1 Fuels and Fossil-Fueled Electricity: Energy Production and Trade
9.2 Nonfossil Contributions: Biomass and Primary Electricity
9.3 Global Consumption Patterns: Growth and Inequality
9.4 Qualitative Changes: Transitions and Efficiencies
9.5 Energy Conservation: Gains and Rebounds
10. Energy Costs: Valuations and Changes
10.1 Energy Cost of Energy: Net Gains
10.2 Basic Materials: from Concrete to Fertilizers
10.3 Structures and Products: From Buildings to Computers
10.4 Crops and Animal Foods: Subsidized Diets
10.5 Modern Food System: Gains, Costs, Efficiencies
11. Environmental Consequences: Metabolism of Fossil-Fueled Civilization
11.1 Power Densities: Energy and Land
11.2 Energy Conversions and Heat Rejection
11.3 Energy and Water
11.4 Energy and the Atmosphere
11.5 Interference in Grand Biospheric Cycles
12 Energetic Correlates: Complexities of High-Energy Civilization
12.1 Energy and the Economy
12.2 Energy and Value
12.3 Energy and the Quality of Life
12.4 Energy and War
12.5 Energy and the Future
13. Grand Patterns: Energetic and Other Essentials
13.1 Energy in the Biosphere
13.2 Energy and Civilization
13.3 The Challenges Ahead
Appendix: Tables of...
SI Units, multiple prefixes (kilo, giga, etc), common energy conversions, energy content of fuels, energy content of foodstuffs, energy flows:31 orders of magnitude, power of continuous phenomena,, power of ephemeral phenomena, efficiencies of common energy conversions, typical energy cost of common materials, global harvests, energy subsidies, and population densities, 1900-2000, table of natural, personal, and energy related risks, population and primary energy 1500-2005, Global Reserves, Resources, and Fluxes of Energies.
Selected Abbreviations, Acronyms, and Symbols
Name Index
Subject Index
Now, my review. How much energy does the Earth receive from the Sun every day? Why are humans able to live in environments ranging from very cold to very hot - a wider range than any other mammal? Could we run our civilization on biofuels, wind power, solar, or geothermal energy? Does extracting uranium from seawater to generate electricity cost more energy than it supplies? How much improvement can we expect in crop yields from genetic engineering? How efficient are compact fluorescent lamps versus incandescent bulbs or the new white LEDs? What was special about James Watt's steam engine?
Professor Smil has made a thorough and wide-ranging survey of the knowledge we have accumulated about energy flows on the grand scale. Inside the book you can find the answers to some of these questions. But, more importantly, in this book you can find enough about the processes involved to be able to assess other people's answers. The book gives you the building blocks to create your own knowledge.
On the negative side, tne book is marred by hundreds of small typos, and grammatical and formatting errors, for example "photovaltaic", "the France", "01.6". Sometimes the mistakes change the sense of what is being said: 1.6MJ per molecule is a whole different kind of energy to 1.6 MJ per mole - 6.02x10<sup>23</sup> molecules. Some diagrams have incorrect units - for example, in fig 3.11 a and b, the horizontal scales are log of body mass, and the vertical scales are log of growth rate and body length respectively. Once or twice, the text and diagrams appear to conflict. These are relatively minor irritations, though.
The book could be improved by including sub-headings or marginal notes when there is a change of topic within a section. For example, section 4.3, Locomotion, compares swimming, flying, and running, and then discusses some details of each in turn. So it has four sub-sections. However, there is no marker in the text to indicate the change of sub-topic. The whole section is just an undifferentiated mass of text, equations, and diagrams.
Never mind. I am satisfied with the book as it is, and I am sure I will be referring to it many times in the coming years.
1. The Universal Link: Energetics, Energy, and Power
1.1 Evolution of Energetics: From Aristotle to Einstein
1.2 Approaches to Understanding: Concepts, Variables, Units
2. Planetary Energetics: Atmosphere, Hydrosphere, Lithosphere
2.1 Sun: The Star and Its Radiation
2.2 Energy Balance of the Earth: Radiation Fluxes
2.3 Hydrophere and Atmosphere: thermal and Mass Fluxes
2.4 Water and Air in Motion: Kinetic Fluxes
2.5 Geoenergetics: Heat, Plate Tectonics, Volcanoes, Earthquakes
3. Photosynthesis: Bioenergetics of Primary Production
3.1 Photosynthetic Pathways
3.2 Global Primary Productivity
3.3 Productivities of Ecosystems and Plants
3.4 Phytomass Stores
3.5 Autotrophic Scaling
4. Heterotrophic Conversions: Consumer Bioenergetics
4.1 Metabolic Capacities
4.2 Ectotherms and Endotherms
4.3 Locomotion
4.4 Biomasses and Productivities
4.5 Heterotrophs in Ecosystems
5. Human Energetics: People as Simple Heterotrophs
5.1 Energy Sources and Basal Metabolism
5.2 Requirements and Uncertainties
5.3 Thermoregulation
5.4 Limits of Human Performance
5.5 Gathering, Hunting, and Fishing
6. Traditional Food Production: Humans as Solar Farmers
6.1 Extensive Practices
6.2 Permanent Cropping
6.3 Muscles, Implements, Machines
6.4 Cropping Intensification
6.5 Traditional Agricultures
7. Preindustrial Complexification: Prime Movers and Fuels in Traditional Societies
7.1 Animal Power: Human and Animal Muscles
7.2 Water and Wind: Wheels and Mills
7.3 Phytomass Fuels and Metallurgy: Wood, Charcoal, Crop Residues
7.4 Construction: Methods and Structures
7.5 Transportation: Roads and Ships
8. Fossil Fuels: Heat, Light, and Prime Movers
8.1 Coals: The Earliest Modern Fuels
8.2 Hydrocarbons: Crude Oils and Natural Gases
8.3 From Extraction to Combustion: Modern Fossil Fuel Industries
8.4 Mechanical Prime Movers: Engines and Turbines
8.5 Fossil-Fueled Electricity: Generation and Transmission
9. Fossil-Fueled Civilization: Patterns and Trends
9.1 Fuels and Fossil-Fueled Electricity: Energy Production and Trade
9.2 Nonfossil Contributions: Biomass and Primary Electricity
9.3 Global Consumption Patterns: Growth and Inequality
9.4 Qualitative Changes: Transitions and Efficiencies
9.5 Energy Conservation: Gains and Rebounds
10. Energy Costs: Valuations and Changes
10.1 Energy Cost of Energy: Net Gains
10.2 Basic Materials: from Concrete to Fertilizers
10.3 Structures and Products: From Buildings to Computers
10.4 Crops and Animal Foods: Subsidized Diets
10.5 Modern Food System: Gains, Costs, Efficiencies
11. Environmental Consequences: Metabolism of Fossil-Fueled Civilization
11.1 Power Densities: Energy and Land
11.2 Energy Conversions and Heat Rejection
11.3 Energy and Water
11.4 Energy and the Atmosphere
11.5 Interference in Grand Biospheric Cycles
12 Energetic Correlates: Complexities of High-Energy Civilization
12.1 Energy and the Economy
12.2 Energy and Value
12.3 Energy and the Quality of Life
12.4 Energy and War
12.5 Energy and the Future
13. Grand Patterns: Energetic and Other Essentials
13.1 Energy in the Biosphere
13.2 Energy and Civilization
13.3 The Challenges Ahead
Appendix: Tables of...
SI Units, multiple prefixes (kilo, giga, etc), common energy conversions, energy content of fuels, energy content of foodstuffs, energy flows:31 orders of magnitude, power of continuous phenomena,, power of ephemeral phenomena, efficiencies of common energy conversions, typical energy cost of common materials, global harvests, energy subsidies, and population densities, 1900-2000, table of natural, personal, and energy related risks, population and primary energy 1500-2005, Global Reserves, Resources, and Fluxes of Energies.
Selected Abbreviations, Acronyms, and Symbols
Name Index
Subject Index
Now, my review. How much energy does the Earth receive from the Sun every day? Why are humans able to live in environments ranging from very cold to very hot - a wider range than any other mammal? Could we run our civilization on biofuels, wind power, solar, or geothermal energy? Does extracting uranium from seawater to generate electricity cost more energy than it supplies? How much improvement can we expect in crop yields from genetic engineering? How efficient are compact fluorescent lamps versus incandescent bulbs or the new white LEDs? What was special about James Watt's steam engine?
Professor Smil has made a thorough and wide-ranging survey of the knowledge we have accumulated about energy flows on the grand scale. Inside the book you can find the answers to some of these questions. But, more importantly, in this book you can find enough about the processes involved to be able to assess other people's answers. The book gives you the building blocks to create your own knowledge.
On the negative side, tne book is marred by hundreds of small typos, and grammatical and formatting errors, for example "photovaltaic", "the France", "01.6". Sometimes the mistakes change the sense of what is being said: 1.6MJ per molecule is a whole different kind of energy to 1.6 MJ per mole - 6.02x10<sup>23</sup> molecules. Some diagrams have incorrect units - for example, in fig 3.11 a and b, the horizontal scales are log of body mass, and the vertical scales are log of growth rate and body length respectively. Once or twice, the text and diagrams appear to conflict. These are relatively minor irritations, though.
The book could be improved by including sub-headings or marginal notes when there is a change of topic within a section. For example, section 4.3, Locomotion, compares swimming, flying, and running, and then discusses some details of each in turn. So it has four sub-sections. However, there is no marker in the text to indicate the change of sub-topic. The whole section is just an undifferentiated mass of text, equations, and diagrams.
Never mind. I am satisfied with the book as it is, and I am sure I will be referring to it many times in the coming years.
19 von 19 Kunden fanden die folgende Rezension hilfreich
Cogent analysis by a keen mind
29. Dezember 2008
Format:Taschenbuch|Von Amazon bestätigter Kauf
A scholarly work relatively free of advocacy, except for advocating sticking to the facts. You will find more pages meticulously diagnosing the history of the energetics of agriculture, transportation and steel making than you will pages forecasting what future energy trends will be, or should be. The author reviews the history of some of these forecast attempts. Here is a sample from page 358: "Reasons for the large number of wrong forecasts can be found in the herdlike behavior of forecasters smitten by prevailing moods". "The U.S. Atomic Energy commission's 1974 forecast had 260 GW installed in the United States by 1985, and 1.2 TW in 2000. The actual 2000 number was 81.5 GW, and there were no clear prospects for fusion." "The same adjectives used to extol nuclear generation - inexhaustible, cheap, nonpolluting - reappeared in glowing descriptions of renewable energetics published during the 1970s as the advocates of small-scale, decentralized energy production promised a new, morally superior millennium devoid of nuclear and fossil fuel sins." And on page 362: "...by the year 2000...new renewables contributed just 3.2 EJ, only one-tenth of Lovins's forecast."
The author wants to avoid falling into Lovins's and the AEC's trap. Nevertheless, scientifically sound constraints on future activity are offered without hesitation, for example: the potential for hydroelectric development, the limits of photosynthesis and geothermal fluxes. But on page 384, the author perhaps becomes polemical: "The ultimate makeup of a new global energy system that may dominate in the second half of the twenty-first century will not resemble currently fashionable scenarios." Notice the choice of words: "will not" rather than "may not". Later on page 382: "I strongly believe that the key to managing future global energy needs is to break with the current expectation of unrestrained energy use in affluent societies." Whose expectation? I live in an affluent society and my energy use is not unrestrained and I don't expect it to be. I presume the sentence applies to other guys, who need to be broken.
Well, let's not nitpick over that sentence. There is no scientific principle more productive than the principle of conservation of energy (my advocacy). There is no analysis of "how stuff works" with greater predictive power than that provided by a monitoring of the energy conversions. This book is a masterpiece by a honest scientist with enormous skill in organizing knowledge of energy.
See MIT Press for a detailed preview inside the book.
The author wants to avoid falling into Lovins's and the AEC's trap. Nevertheless, scientifically sound constraints on future activity are offered without hesitation, for example: the potential for hydroelectric development, the limits of photosynthesis and geothermal fluxes. But on page 384, the author perhaps becomes polemical: "The ultimate makeup of a new global energy system that may dominate in the second half of the twenty-first century will not resemble currently fashionable scenarios." Notice the choice of words: "will not" rather than "may not". Later on page 382: "I strongly believe that the key to managing future global energy needs is to break with the current expectation of unrestrained energy use in affluent societies." Whose expectation? I live in an affluent society and my energy use is not unrestrained and I don't expect it to be. I presume the sentence applies to other guys, who need to be broken.
Well, let's not nitpick over that sentence. There is no scientific principle more productive than the principle of conservation of energy (my advocacy). There is no analysis of "how stuff works" with greater predictive power than that provided by a monitoring of the energy conversions. This book is a masterpiece by a honest scientist with enormous skill in organizing knowledge of energy.
See MIT Press for a detailed preview inside the book.
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