| Description |
1 online resource |
| Contents |
Ts -- Part 1. Theory -- To Understand Economics, Follow the Money: To Understand Ecosystems, Follow the Energy -- Two Views of Ecology, Evolution, and Conservation -- Why I Wrote this Book -- Dualities Still Impede Conservation Efforts -- The Intergovernmental Science-Policy Platform of Biodiversity -- Targets for Conservation -- Evolving Objectives -- Literature Review -- Updating Ecosystem Ecology -- References -- What Can We Learn by Studying Ecosystems that We Can't Learn from Studying Populations? -- The Predator-Prey Conundrum -- The Serengeti Ecosystem -- Evolution in the "Ecological Theater" -- Predator-Prey Interactions Tell Only Part of the Story -- Evolution in the "Thermodynamic Theater" -- References -- A Thermodynamic Definition of Ecosystems -- Ecosystems in the 20th Century -- Cycling of Strontium-90 -- Cesium-137 in Food Chains -- Recycling of Isotopes in Norwegian Sheep -- Ecological Energetics -- Is it Time to Bury the Ecosystem Concept? -- A Thermodynamic Definition of Life -- A Thermodynamic Definition of Ecosystems -- The Phase Transition between Order and Chaos -- References -- Thermodynamic Characteristics of Ecosystems -- Equilibrium -- The Equilibrium Law -- Thermodynamic Equilibrium -- Open Thermodynamic Systems -- Ecosystems are Thermodynamically Open Non-Equilibrium Systems -- Work is Performed by Non-equilibrium Systems -- Advantage of a Thermodynamically Open System -- 4.3 Ecosystems are Entropic -- 4.4 Ecosystems are Cybernetic -- Cybernetic Systems -- Economic Systems are Cybernetic Ecosystems are Cybernetic -- The Ecosystem Feedback Function -- Indirect vs. Direct Feedback -- Deviation Dampening and Amplifying Feedback -- Set Points -- Ecosystems are Autocatalytic -- Ecosystems have Boundaries -- Ecosystems are Hierarchical -- Hierarchy in Physical Systems -- Hierarchy in Ecological Systems -- Common Currencies -- Macro-and Micro-System Models -- Why an Ecosystem Model that Includes Everything is not Possible -- A Nested Marine Community -- Ecosystems are Deterministic -- Ecosystems are Information Rich -- An Engineering Definition of Information -- Information to Facilitate Exchange -- High Energy Information -- Low Energy Information -- Information Theory -- Genetic Information -- Ecosystems are Non-Teleological -- Criticisms of Ecosystem Models -- References -- Ecosystem Control: A Top-Down View -- Two Ways to Look at Systems -- Composing and Decomposing Trophic Webs -- Decomposers in Soil Organic Matter -- Decomposers in Marshes and Mangroves -- Control of Systems -- Top-Down vs. Bottom-Up -- Top-Down Exogenous Control -- Exogenous Impacts and Stability -- Top-Down Endogenous Control -- Endogenous Control through Nutrient Recycling -- Autocatalysis -- Control of Microbial Activity -- Inhibition of Microbial Activity by Leaf Sclerophylly -- Inhibition of Microbial Activity Chemical Defenses -- Inhibition of Microbial Activity by Ecological Stoichiometry -- The Synchrony Principle -- The Decay Law -- Direct Nutrient Cycling -- The Role of Animals -- Indirect Interactions -- Marine Systems -- Nutrient and Energy Recycling -- Exogenous Control -- Control in Lakes -- Control in Managed Ecosystems -- References -- Ecosystem Control: A Bottom-Up View -- Species as Arbitrageurs of Energy -- Relation Between Rate of Flow and Mass in Hydraulic Systems -- Relation Between Population Biomass and Rate of Energy Flow -- Equilibrium -- Mechanisms of Adjustment -- Adjustments and Climate Change -- Bird Populations -- Dis-equilibrium -- Population Instability vs. Ecosystem Instability -- Control by Interactions: Direct vs. Indirect -- Indirect Interactions -- Direct Interactions -- Predator - Prey -- Mutualisms -- Competition -- Decomposition -- Parasitism and Disease -- Commensalism and Amensalism -- Persistence of Negative Interactions -- References -- Ecosystem Stability -- Background -- A Thermodynamic Definition -- Regime Shift -- Metastability -- Pulsed Stability -- Resistance and Resilience -- Species Richness and Functional Stability -- Species Richness and Cultural Values -- Keystone Species, and Population and Ecosystem Stability -- 7.5.1 Keystone Species in the Yellowstone region of Wyoming -- References -- 8. Case Studies of Ecosystem Control and Stability -- Walden -- "Harmony in Nature" -- Feedback Produces Nature's "Harmony" -- Feedback Mechanisms -- Perturbations in Amazon Rain Forests -- Top-Down Control -- The San Carlos Project: A Small-scale, Low Intensity, Short Duration Disturbance -- 8.3.2 The Jarí Project: A Large-scale, High Intensity, Long Duration Disturbance -- Bottom-Up Control -- The El Verde Project -- The Long-Term Ecological Research Project in Puerto Rico -- The Lago Guri Island Project -- The Biological Dynamics of Tropical Rainforest Fragments Project -- What have Case Studies Taught us about Stability of Tropical Ecosystems? -- Tropical Ecosystems are Stable -- Tropical Ecosystems are Unstable -- Energy Flow in Tropical Savannas and Rain Forests -- Insects in Tropical Ecosystems -- Application of Lessons to Other Regions -- Relevance to Temperate Zones -- Relevance to Aquatic Ecosystems -- The Experimental Lakes Project (Ecosystem Control of Species) -- Lake Mendota Studies (Species Control of Ecosystems) -- 8.7 Case Studies as Tests of Thermodynamic Theory -- References -- Entropy and Maximum Power -- Entropy -- 9.2 Entropy in a Steel Bar -- Thermodynamic Equilibrium -- Entropic Gradients -- Capturing and Storing Entropy -- Evapotranspiration and Entropy Reduction -- Life is a Balance between Storing and Releasing Entropy -- The Law of Maximum Entropy Production -- Energy for Metabolism as well as Growth -- Unassisted Entropy Capture is a Unique Characteristic of Life.-9.6Entropy Storage by Ecosystems -- 9.6.1 What Causes Entropy to be Stored? -- 9.7 Capturing Pressure -- 9.8 Entropy and Time -- 9.8.1 Time's Speed Regulator -- Efficiency of Energy Transformations -- Passage of Time for Cats -- 9.9The Maximum Power Principle.-9.10 Optimum Efficiencies for a Truck and its Driver.-9.11 Sustainability -- References -- A Thermodynamic View of Succession -- 10.1 The Population View -- 10.2 The Thermodynamic View -- 10.2.1 Leaf Area Index and Succession -- 10.2.2 Power Output as a Function of Leaf Area Index -- 10.2.3 What Causes Changes in Leaf Area Index? -- 10.2.4 Maximum Entropy Production Principle -- 10.2.5 Successional Ecosystems Move Further from Thermodynamic Equilibrium -- 10.2.6 Entropy Storage by Animals -- 10.3 The Strategy of Ecosystem Development -- A Problem with Odum's Strategy -- Why Power Output Continues to Increase -- Revised Definition of Maximum Power -- Costs of Ecosystem Stabilization -- Transactional Costs -- Succession, Power Output, and Efficiency -- 10.5.1 Kleiber's Law -- Are Ecosystems Spendthrifts? -- Interactions Between Species Facilitate Increase in Power Output -- Facilitation -- Tolerance -- Inhibition -- Intermediate Disturbance Hypothesis -- Nutrient Use Efficiency during Succession -- Succession Following Logging vs Following Agriculture -- 10.10 Thermodynamic View of Succession: Implications for Resource Management -- References -- Panarchy -- The Universal Cycle of Systems -- Panarchy -- Thermodynamic Interpretation of the Sacred Rules -- 11.2.1 Growth and Consolidation -- 11.2.2 Collapse -- Renewal -- Sub-systems -- Panarchy over 2 Billion Years of Evolution -- Consolidation, Bureaucracy and System Collapse -- Bureaucracy in Action (Case Studies) -- Case Study: Panarchy in the Georgia Piedmont -- Thermodynamic Interpretation -- References -- 12. A Thermodynamic View of Evolution -- 12.1 Life - A Physicist's View -- 12.1.1 Life is Produced by Capturing Entropy -- 12.1.2 The Origin of Life -- 12.2 Two Approaches to Evolution -- 12.2.1 The Eco-Evo-Devo View -- 12.2.2 The Thermodynamic View -- 12.2.3 Fitness -- 12.2.4 The "Goal" of Evolution -- 12.3 The Relationship between Species and Environment -- 12.3.1 Evolution's "Theater" -- 12.3.2 Is Evolution Stochastic or Deterministic? -- 12.4 Ecosystem Evolution -- 12.4.1 Succession was the Clue -- 12.4.2 Ecosystems Moved away from Equilibrium -- 12.4.3 Thermodynamic Mechanisms -- 12.4.4 Biological Mechanisms -- 12.4.5 Ecosystem Fitness -- 12.4.6 Ecosystems Evolve One Step at a Time -- 12.5. The Origin of Ecosystems -- 12.5.1 Origin of Feedback Loops -- 12.5.2 Origin of Trophic Levels -- 12.5.3 Why are there Trophic Levels? -- 12.6 The "Goal" of Ecosystem Evolution -- 12.6.1 Conflicting Goals? -- 12.6.2 "Motivations" of Species -- 12.6.3 The Earth Ecosystem -- 12.6.4 Why is there Resistance to the Idea of Ecosystem Evolution? -- 12.6.5 Evolution of Economic Systems -- 12.7 A Thermodynamic Model of Ecosystem Evolution -- 12.7.1 Network Models -- 12.7.2 Increase in Complexity of Trophic Webs -- 12.7.3 Evolution of Trophic Webs -- 12.7.4 Life Moves Ashore -- 12.8 Biodiversity and the Five Great Extinctions -- 12.8.1 The Cretaceous-Tertiary (K-T) Boundary Extinction -- 12.8.2The Amazing Sustainability of Trophic Chains -- 12.8.3 A Test of Thermodynamic Theory -- 12.9 Panarchy and Evolution -- 12.10 Thermodynamic Requirements for Living Systems on Other Planets -- References -- Why is Species Diversity Higher in the Tropics? -- 13.1 Tropical Explorations -- 13.2 A Few Theories -- 13.3 A Thermodynamic Explanation -- 13.3.1 The Latitudinal Energy Gradient -- 13.3.2 The Latitudinal Productivity Gradient -- 13.3.3 The Data -- 13.3.4 Other Factors Affecting Productivity -- 13.4 Empirical Evidence for a High Productivity High Diversity Correlation -- 13.5 Humboldt's Enigma -- 13.5.1 Are Productivity and Species Richness Correlated on Tropical -- Mountains? -- 13.6 The Mechanism Linking Productivity and Diversity -- 13.7 Answer to "Why is Species Diversity Higher in the Tropics?" -- 13.7.1 Differences within the Tropics -- 13.8 Why is Species Diversity Low at High Latitudes? -- 13.9 An Economic Perspective on D |
| Summary |
"Survival of the fittest" is a tautology, because those that are "fit" are the ones that survive, but to survive, a species must be "fit." Modern evolutionary theory avoids the problem by defining fitness as reproductive success, but the complexity of life that we see today could not have evolved based on selection that favors only reproductive ability. There is nothing inherent in reproductive success alone that could result in higher forms of life. Evolution from a Thermodynamic Perspective presents a non-circular definition of fitness and a thermodynamic definition of evolution. Fitness means maximization of power output, necessary to survive in a competitive world. Evolution is the "storage of entropy." "Entropy storage" means that solar energy, instead of dissipating as heat in the Earth, is stored in the structure of living organisms and ecosystems. Part one explains this in terms comprehensible to a scientific audience beyond biophysicists and ecosystem modelers. Part two applies thermodynamic theory in non-esoteric language to sustainability of agriculture, and to conservation of endangered species. While natural systems are stabilized by feedback, agricultural systems remain in a mode of perpetual growth, pressured by balance of trade and by a swelling population. The constraints imposed by thermodynamic laws are being increasingly felt as economic expansion destabilizes resource systems on which expansion depends |
| Bibliography |
Includes bibliographical references |
| Notes |
Online resource; title from PDF title page (SpringerLink, viewed December 9, 2021) |
| Subject |
Evolution (Biology)
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Thermodynamics.
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Conservation biology.
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Thermodynamics
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thermodynamics.
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Conservation biology
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Evolution (Biology)
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Thermodynamics
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Evolució (Biologia)
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Termodinàmica.
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Biologia de la conservació.
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| Genre/Form |
Llibres electrònics.
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| Form |
Electronic book
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| ISBN |
9783030851866 |
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3030851869 |
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