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100   $a20080916d2008      uy             0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 14$aThe entropy crisis$b[electronic resource] /$fGuy Deutscher
210   $aNew Jersey $cWorld Scientific$dc2008
215   $a1 online resource (184 p.)
300   $aIncludes index.
311   $a981-277-969-8 
311   $a981-277-968-X 
327   $aContents; Introduction; Chapter 1. Dealing with Entropy on a Daily Basis; 1.1. Entropy in the household; 1.2. An example of an entropy crisis at home; 1.3. Where does all the disorder go?; 1.4. Disorder and pollution; 1.5. Entropy and the second law of thermodynamics; 1.5.1. Water desalination; 1.5.2. Heat transfer; 1.5.3. Entropy and the states of matter; 1.6. From the household to the biosphere; Chapter 2. A Short History of the Biosphere; 2.1. The billion year time scale; 2.1.1. The apparition of life; 2.1.2. Photosynthesis; 2.1.2.1. Photosynthesis and entropy reduction
327   $a2.1.2.2. Photosynthesis and the green color of plants2.1.3. The ozone layer and the spread of life; 2.2. The biosphere on the 100 million year time scale; 2.2.1. Carbon dioxide atmospheric content and temperature: the greenhouse effect; 2.2.1.1. The infrared radiation; 2.2.1.2. Greenhouse gases; 2.2.2. Climate evolution and carbon storage; 2.3. Carbon storage: carbonates and fossil fuels; 2.3.1. Carbon storage in carbonates on the billion year time scale; 2.3.2. Carbon storage as fossil fuels on the 100 million year time scale; 2.3.3. Formation of coal deposits: the carboniferous age
327   $a2.3.4. Oil and gas deposits2.4. Ice ages; 2.5. The last 10 million years; Chapter 3. How Much Energy do We Need?; 3.1. Different forms of energy and power; 3.2. Energy conversion; 3.3. Energy use and entropy release; 3.3.1. Heat rejection; 3.3.2. Entropy release; 3.4. Energy needs and costs; 3.4.1. Food energy; 3.4.2. Food versus other energy needs; 3.4.3. A family's energy needs; 3.4.4. A family's energy costs; 3.4.4.1. Food energy costs; 3.4.4.2. The different energy costs; 3.4.5. Energy needs at the society level and the entropy problem
327   $a3.5. Can society survive with a lower entropy release?Chapter 4. Entropy in Thermodynamics and Our Energy Needs; 4.1. Entropy in thermodynamics; 4.1.1. Heat and mechanical work as two forms of energy: the first law of thermodynamics; 4.1.2. Thermodynamic cycles; 4.1.3. Work performed in a thermodynamic cycle; 4.1.4. The Carnot cycle; 4.1.5. Entropy change: introducing the second law of thermodynamics; 4.1.6. Energy, entropy and free energy; 4.2. Entropy at the molecular level; 4.3. Energy needs and man generated entropy; Chapter 5. Climate Change: What We Know and What We Don't
327   $a5.1. Time scale and temperature scale5.1.1. The earth's temperature over the last few hundred thousand years; 5.1.2. How well understood is the periodicity of interglacial periods; 5.1.3. The Milankovitch cycles; 5.1.4. Problems with the Milankovitch cycles; 5.1.5. Towards a longer interglacial period?; 5.2. The CO2 cycles; 5.3. Anthropogenic temperature changes; 5.3.1. The CO2 anthropogenic footprint; 5.3.2. The temperature rise in modern times; 5.3.2.1. Evolution of the temperature since 1900: the start of anthropogenic effects; 5.3.2.2. Expected temperature rise in the 21st century
327   $a5.3.2.3. Consequences of further temperature rise: ice melting
330   $aThis book aims to prove that the so-called "energy crisis" is really an entropy crisis. Since energy is conserved, it is clear that a different concept is necessary to discuss meaningfully the problems posed by energy supplies and environmental protection. This book makes this concept, entropy, accessible to a broad, nonspecialized audience.Examples taken from daily experiences are used to introduce the concept of entropy in an intuitive manner, before it is defined in a more formal way. It is shown that the entropy increase due to irreversible transformations (or "unrecoverable" energy) simul
606   $aEnergy development
606   $aPower resources
606   $aEntropy
606   $aEnvironmental protection
606   $aClimatic changes
615  0$aEnergy development.
615  0$aPower resources.
615  0$aEntropy.
615  0$aEnvironmental protection.
615  0$aClimatic changes.
676   $a333.79
700   $aDeutscher$b Guy$0317756
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910777935803321
996   $aThe entropy crisis$93737390
997   $aUNINA