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Additional Edition: Erscheint auch als Druck-Ausgabe Solar & wind technology Oxford [u.a.] ; Frankfurt : Pergamon Pr., 1984-1990 ISSN 0741-983X

Later: Forts.: Renewable energy

Language: English

Keywords: Zeitschrift ; Zeitschrift ; Zeitschrift

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Format: 1 online resource (271 pages)

Edition: 1st ed.

ISBN: 9783030031527

Note: Understanding Risks and Uncertainties in Energy and Climate Policy -- Foreword -- Editorial -- Organisation of the Book -- Acknowledgement -- Contents -- About the Editors -- A Detailed Overview and Consistent Classification of Climate-Economy Models -- 1 Introduction -- 2 Classifying Climate-Economy Models -- 3 Optimal Growth Models -- 4 Computable General Equilibrium Models -- 5 Partial Equilibrium Models -- 6 Energy System Models -- 7 Macroeconometric Models -- 8 Other Integrated Assessment Models -- 9 Concluding Remarks -- References -- ``Consensus Building in Engagement Processes ́́for Reducing Risks in Developing Sustainable Pathways: Indigenous Interest as C... -- 1 Introduction -- 2 Previous and Current Studies Integrating Indigenous Knowledge and Climate Change -- 3 Inclusion of Indigenous Interests: Free, Prior and Informed Consent -- 4 Indigenous Legal Rights and Consultation Process in Canada -- 5 Risks Identified in the Current Consultation Process Within the Canadian Context -- 5.1 Government Aspect -- 5.2 Indigenous Aspect -- 5.3 Industry Aspect -- 5.4 Who Bears the Responsibility? -- 6 Understanding Indigenous Ways of Knowing and World Views as Essential Step Towards Inclusion -- 6.1 Respect -- 6.2 Relevant -- 6.3 Reciprocating -- 6.4 Responsibility -- 7 Framework -- 7.1 Pre-assessment -- 7.2 Development: Listening and Conversations -- 7.3 Implementation: Inclusion and Accommodation -- 7.4 Monitoring and Learning: Responsibility and Accommodation -- 7.5 Reflection: Lessons -- 8 Conclusions -- References -- An Application of Calibration and Uncertainty Quantification -- 1 Introduction -- 2 The ABM for the Diffusion of Small-Scale Solar PV -- 3 The Concept of Emulators -- 3.1 Gaussian Processes for Regression -- 3.2 Benefits of Using Gaussian Processes as Emulators -- 4 The Design and Validation of the GP Emulator. , 4.1 Options for the Emulator Form -- 4.2 Fitting the GP Emulator -- 4.3 Diagnostics -- 4.4 Sensitivity Analysis -- 5 Model Calibration -- 5.1 The History Matching Method -- 5.2 The Patient Rule Induction Method -- 5.3 Calibration and Extrapolation Results -- 6 Discussion -- References -- Investments in the EU Power System: A Stress Test Analysis on the Effectiveness of Decarbonisation Policies -- 1 Introduction -- 2 Modelling Investments in Electricity Generation and Transmission -- 2.1 Short-Term vs. Long-Term Considerations for Optimal Portfolio -- 2.2 EMPIRE Model Formulation -- 3 Energy Transition: Cases and EMPIRE Model Results -- 3.1 Defining Cases -- 3.2 Results for 2020-2030 Period: All Cases -- 3.3 Results for Reference Cases 2030-2050 -- 3.4 Results for Decarbonisation Cases 2030-2050 -- 4 Robustness Tool and Stress Testing the Optimal Portfolios -- 5 Conclusions -- Appendices -- Appendix 1 Nomenclature Used in the EMPIRE Model Formulation -- Appendix 2 Technological Assumptions for EMPIRE Implementation -- References -- Impact Assessment of Climate and Energy Policy Scenarios: A Multi-criteria Approach -- 1 Introduction -- 2 Defining the Problem -- 2.1 The Scenarios -- 2.2 The Multi-criteria Evaluation System -- 2.2.1 The Criteria -- 2.2.2 The PROMETHEE Method -- 2.2.3 Simos Procedure -- 3 Pilot Application and Scenario Analysis -- 4 Conclusions -- References -- Water Stress Implications of Energy Scenarios for the Middle East: An Assessment of Risks and Uncertainties -- 1 Introduction -- 2 The Energy-Water-Food Nexus -- 3 Case Study on the Middle East -- 4 Results and Discussion -- 5 Conclusions and Recommendations -- Appendix -- References -- Evaluation of National Environmental Efficiency Under Uncerta -- 1 Introduction -- 2 Literature Review -- 3 Methodology -- 3.1 General -- 3.2 Envelopment Models -- 3.3 Slack-Based Models. , 3.4 Incorporating Uncertainty -- 3.5 Data and Modeling -- 4 Results -- 4.1 SBEI Results for Model A -- 4.2 SBEI Results for Model B -- 4.3 Stochastic Efficiency -- 5 Concluding Remarks -- References -- Hypothesis for a Risk Cost of Carbon: Revising the Externalities and Ethics of Climate Change -- 1 Introduction -- 1.1 Externalized Cost of Carbon -- 1.2 Positive Carbon Price -- 1.3 Climate Systemic Risk -- 1.4 Biophysical Economics -- 1.5 Future Carbon Emissions -- 1.6 Network Theory -- 2 Holistic Market Hypothesis -- 2.1 Risk Cost of Carbon -- 2.2 Market Policy Dualism -- 2.3 Epistemology of Complementary Relationships -- 3 Global Carbon Reward -- 3.1 Policy Background -- 3.2 Policy Framework -- 3.3 Parallel Currency -- 3.4 Financial Mechanism -- 3.5 Risk Assessments -- 4 Analytical Verification -- 4.1 Premise -- 4.2 Epistemological Translation -- 4.3 Axioms -- 4.4 Translation for Price Reversal (Step 1) -- 4.5 Translation for Currency Units (Step 2) -- 4.6 Translation for the Arrow of Time (Step 3) -- 4.7 Comparative Check for Time Asymmetry -- 5 Discussion -- 5.1 Theoretical Cogency -- 5.1.1 Interdisciplinary Interpretation -- 5.1.2 Experimental Testing -- 5.1.3 Resolution of the Temporal Paradox -- Time Discounting of Consumption -- Time Discounting of Investments -- 5.2 Practical Applications -- 5.2.1 The Paris Climate Agreement -- 5.2.2 Achieving Net Zero Emissions -- 5.2.3 Managing Global Growth -- 5.3 Philosophy and Ethics -- 6 Concluding Remarks -- 7 Research Recommendations -- References -- Assessment of Renewable Energy Projects Using a Decision Support System: A Process to Endorse the Social License to Operate -- 1 Introduction -- 2 Methodological Framework -- 3 The Evaluated Hypothetical Scenarios and Discussion -- 4 Conclusions -- References -- A Unilateral Climate and Supply Market Model. , 1 Energy Policy and the Concept of Direct and Multiple Steering -- 2 Current Issues of the EU ETS -- 3 Existing Carbon Taxation Models -- 3.1 Differential Taxation -- 3.2 Carbon Tax with Border Tax Adjustments -- 3.3 United Kingdom: Carbon Price Floor -- 4 Unilateral Climate and Supply Market Model -- 5 Legal Considerations with Respect to International and EU Law -- 6 Climate and Supply Market Model Example: Switzerland -- 7 Variations of the Climate and Supply Market Model -- 8 Adaption Potential for the Climate and Supply Market Model -- 9 Conclusion -- References.

Additional Edition: Print version: Doukas, Haris Understanding Risks and Uncertainties in Energy and Climate Policy Cham : Springer International Publishing AG,c2018 ISBN 9783030031510

Language: English

Subjects: Economics

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Format: 1 online resource (535 pages)

Edition: 1st ed.

ISBN: 9783030058432

Note: Intro -- Dedication -- Climate Model: Foreword -- Contact Information -- Executive Summary -- Acknowledgement -- Contents -- List of Figures -- List of Tables -- Chapter 1: Introduction -- References -- Chapter 2: State of Research -- 2.1 Scientific Status Quo of Climate Change Research -- 2.1.1 Basics of Climate Change and Radiative Forcing -- 2.1.1.1 Anthropogenic Contribution -- 2.1.1.2 Carbon Budget and Future Warming -- 2.1.2 Carbon Budgets for 1.5 °C and 2.0 °C Warming -- 2.2 Development of Energy Markets-Past and Present -- 2.2.1 Global Trends in Renewable Energy in 2018 -- 2.2.1.1 Trends in the Renewable Power Sector -- 2.2.1.2 Heating and Cooling -- 2.2.1.3 Transport -- References -- Chapter 3: Methodology -- 3.1 100% Renewable Energy-Modelling Approach -- 3.2 Global Mapping-Renewable Energy Potential in Space-Constrained Environments: [R]E-SPACE -- 3.3 Transport Energy Model-TRAEM -- 3.3.1 Transport Model Structure -- 3.3.2 Transport Data -- 3.3.3 Transport Model Output -- 3.4 Energy System Model (EM) -- 3.5 [R]E 24/7 (UTS-ISF) -- 3.5.1 [R]E 24/7-Model Structure -- 3.5.2 Development and Calculation of Load Curves -- 3.5.3 Load Curve Calculation for Households -- 3.5.4 Load Curve Calculation for Business and Industry -- 3.5.5 Load Distribution by Cluster -- 3.5.6 The [R]E 24/7 Dispatch Module -- 3.5.7 Meteorological Data -- 3.5.7.1 Solar and Wind Time Series -- 3.5.8 Interconnection Capacities -- 3.6 Employment Modelling (UTS-ISF) -- 3.6.1 Quantitative Employment Calculation -- 3.6.2 Occupational Employment Modelling -- 3.7 Material and Metal Resources Analysis (UTS-ISF) -- 3.7.1 Methodology-Material and Metal Resources Analysis -- 3.8 Climate Model -- 3.8.1 Deriving Non-CO2 GHG Pathways -- 3.8.1.1 Regional Definitions -- 3.8.1.2 Harmonization: Emission Category Adjustments -- 3.8.1.3 A New Quantile Regression Method for Non-CO2 Gases. , 3.8.1.4 'Pseudo' Fossil and Industrial CO2 Extensions Beyond 2050 -- 3.8.1.5 Land-Use Assumptions -- 3.8.2 Model for the Assessment of GHG-Induced Climate Change -- References -- Chapter 4: Mitigation Scenarios for Non-energy GHG -- 4.1 Land-Use CO2 emissions -- 4.1.1 Other GHG and Aerosol Emissions -- References -- Chapter 5: Main Assumptions for Energy Pathways -- 5.1 Scenario Definition -- 5.1.1 The 5.0 °C Scenario (Reference Scenario) -- 5.1.2 The 2.0 °C Scenario -- 5.1.3 The 1.5 °C Scenario -- 5.2 Scenario World Regions and Clusters -- 5.2.1 OECD North America -- 5.2.2 Latin America -- 5.2.3 OECD Europe -- 5.2.4 Eastern Europe/Eurasia -- 5.2.5 The Middle East -- 5.2.6 Africa -- 5.2.7 Non-OECD Asia -- 5.2.8 India -- 5.2.9 China -- 5.2.10 OECD Pacific -- 5.3 Key Assumptions for Scenarios -- 5.3.1 Population Growth -- 5.3.2 GDP Development -- 5.3.3 Technology Cost Projections -- 5.3.3.1 Power and CHP Technologies -- 5.3.3.2 Heating Technologies -- 5.3.4 Fuel Cost Projections -- 5.3.4.1 Fossil Fuels -- 5.3.4.2 Biomass Prices -- 5.3.5 CO2 Costs -- 5.4 Energy Scenario Narratives and Assumptions for World Regions -- 5.4.1 Efficiency and Energy Intensities -- 5.4.1.1 Industrial Electricity Demand -- 5.4.1.2 Demand for Fuel to Produce Heat in the Industry Sector -- 5.4.1.3 Electricity Demand in the 'Residential and Other' Sector -- 5.4.1.4 Fuel Demand for Heat in the 'Residential and Other' Sector -- 5.4.1.5 Resulting Energy Intensities by Region -- 5.4.2 RES Deployment for Electricity Generation -- 5.4.3 RES Deployment for Heat Generation -- 5.4.4 Co-generation of Heat and Power and District Heating -- 5.4.5 Other Assumptions for Stationary Processes -- References -- Chapter 6: Transport Transition Concepts -- 6.1 Introduction -- 6.2 Global Transport Picture in 2015 -- 6.3 Measures to Reduce and Decarbonise Transport Energy Consumption. , 6.3.1 Powertrain Electrification -- 6.3.1.1 The 5.0 °C Scenario -- 6.3.1.2 The 2.0 °C Scenario -- 6.3.1.3 The 1.5 °C Scenario -- 6.3.2 Mode-Specific Efficiency and Improvements Over Time -- 6.3.3 Road Transport -- 6.3.3.1 Passenger Cars -- 6.3.3.2 Light and Heavy Freight Vehicles -- 6.3.3.3 Buses -- 6.3.3.4 Two- and Three-Wheel Vehicles -- 6.3.3.5 Rail Transport -- 6.3.3.6 Water and Air Transport -- 6.3.4 Replacement of Fossil Fuels by Biofuels and Synfuels -- 6.3.5 Operational Improvements and Novel Service Concepts -- 6.3.5.1 Passenger Transport -- 6.3.5.2 Freight Transport -- 6.4 Transport Performance -- 6.4.1 Passenger Transport Modes -- 6.4.2 Freight Transport Modes -- References -- Chapter 7: Renewable Energy Resource Assessment -- 7.1 Global Renewable Energy Potentials -- 7.1.1 Bioenergy -- 7.2 Economic Renewable Energy Potential in Space-Constrained Environments -- 7.2.1 Constrains for Utility-Scale Solar and Wind Power Plants -- 7.2.2 Mapping Solar and Wind Potential -- References -- Chapter 8: Energy Scenario Results -- 8.1 Global: Long-Term Energy Pathways -- 8.1.1 Global: Projection of Overall Energy Intensity -- 8.1.2 Global: Final Energy Demand by Sector (Excluding Bunkers) -- 8.1.3 Global: Electricity Generation -- 8.1.4 Global: Future Costs of Electricity Generation -- 8.1.5 Global: Future Investments in the Power Sector -- 8.1.6 Global: Energy Supply for Heating -- 8.1.7 Global: Future Investments in the Heating Sector -- 8.1.8 Global: Transport -- 8.1.9 Global: Development of CO2 Emissions -- 8.1.10 Global: Primary Energy Consumption -- 8.2 Global: Bunker Fuels -- 8.3 Global: Utilization of Solar and Wind Potential -- 8.4 Global: Power Sector Analysis -- 8.4.1 Global: Development of Power Plant Capacities -- 8.4.2 Global: Utilization of Power-Generation Capacities -- 8.4.3 Global: Development of Load, Generation, and Residual Load. , 8.4.4 Global System-Relevant Technologies-Storage and Dispatch -- 8.4.5 Global: Required Storage Capacities for the Stationary Power Sector -- 8.5 OECD North America -- 8.5.1 OECD North America: Long-Term Energy Pathways -- 8.5.1.1 OECD North America: Final Energy Demand by Sector -- 8.5.1.2 OECD North America: Electricity Generation -- 8.5.1.3 OECD North America: Future Costs of Electricity Generation -- 8.5.1.4 OECD North America: Future Investments in the Power Sector -- 8.5.1.5 OECD North America: Energy Supply for Heating -- 8.5.1.6 OECD North America: Future Investments in the Heating Sector -- 8.5.1.7 OECD North America: Transport -- 8.5.1.8 OECD North America: Development of CO2 Emissions -- 8.5.1.9 OECD North America: Primary Energy Consumption -- 8.5.2 Regional Results: Power Sector Analysis -- 8.5.3 OECD North America: Power Sector Analysis -- 8.5.3.1 OECD North America: Development of Power Plant Capacities -- 8.5.3.2 OECD North America: Utilization of Power-Generation Capacities -- 8.5.3.3 OECD North America: Development of Load, Generation, and Residual Load -- 8.6 Latin America -- 8.6.1 Latin America: Long-Term Energy Pathways -- 8.6.1.1 Latin America: Final Energy Demand by Sector -- 8.6.1.2 Latin America: Electricity Generation -- 8.6.1.3 Latin America: Future Costs of Electricity Generation -- 8.6.1.4 Latin America: Future Investments in the Power Sector -- 8.6.1.5 Latin America: Energy Supply for Heating -- 8.6.1.6 Latin America: Future Investments in the Heating Sector -- 8.6.1.7 Latin America: Transport -- 8.6.1.8 Latin America: Development of CO2 Emissions -- 8.6.1.9 Latin America: Primary Energy Consumption -- 8.6.2 Latin America: Power Sector Analysis -- 8.6.2.1 Latin America: Development of Power Plant Capacities -- 8.6.2.2 Latin America: Utilization of Power-Generation Capacities. , 8.6.2.3 Latin America: Development of Load, Generation and Residual Load -- 8.7 OECD Europe -- 8.7.1 OECD Europe: Long-Term Energy Pathways -- 8.7.1.1 OECD Europe: Final Energy Demand by Sector -- 8.7.1.2 OECD Europe: Electricity Generation -- 8.7.1.3 OECD Europe: Future Costs of Electricity Generation -- 8.7.1.4 OECD Europe: Future Investments in the Power Sector -- 8.7.1.5 OECD Europe: Energy Supply for Heating -- 8.7.1.6 OECD Europe: Future Investments in the Heating Sector -- 8.7.1.7 OECD Europe: Transport -- 8.7.1.8 OECD Europe: Development of CO2 Emissions -- 8.7.1.9 OECD Europe: Primary Energy Consumption -- 8.7.2 OECD Europe: Power Sector Analysis -- 8.7.2.1 OECD Europe: Development of Power Plant Capacities -- 8.7.2.2 OECD Europe: Utilization of Power-Generation Capacities -- 8.7.2.3 OECD Europe: Development of Load, Generation, and Residual Load -- 8.8 Africa -- 8.8.1 Africa: Long-Term Energy Pathways -- 8.8.1.1 Africa: Final Energy Demand by Sector -- 8.8.1.2 Africa: Electricity Generation -- 8.8.1.3 Africa: Future Costs of Electricity Generation -- 8.8.1.4 Africa: Future Investments in the Power Sector -- 8.8.1.5 Africa: Energy Supply for Heating -- 8.8.1.6 Africa: Future Investments in the Heating Sector -- 8.8.1.7 Africa: Transport -- 8.8.1.8 Africa: Development of CO2 Emissions -- 8.8.1.9 Africa: Primary Energy Consumption -- 8.8.2 Africa: Power Sector Analysis -- 8.8.2.1 Africa: Development of Power Plant Capacities -- 8.8.2.2 Africa: Utilization of Power-Generation Capacities -- 8.8.2.3 Africa: Development of Load, Generation, and Residual Load -- 8.9 The Middle East -- 8.9.1 The Middle East: Long-Term Energy Pathways -- 8.9.1.1 The Middle East: Final Energy Demand by Sector -- 8.9.1.2 The Middle East: Electricity Generation -- 8.9.1.3 The Middle East: Future Costs of Electricity Generation. , 8.9.1.4 The Middle East: Future Investments in the Power Sector.

Additional Edition: Print version: Teske, Sven Achieving the Paris Climate Agreement Goals Cham : Springer International Publishing AG,c2019 ISBN 9783030058425

Language: English

Subjects: General works

Keywords: Electronic books.

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Format: 1 online resource (181 pages)

Edition: 1st ed.

ISBN: 9783030104276

Note: Intro -- Preface -- Why This Book? -- The Goal of This Book -- What's in This Book? -- Acknowledgments -- Contents -- Nomenclature -- List of Figures -- List of Tables -- Executive Summary -- 1 eIoT as a Solution to Energy-Management Change Drivers -- 1.1 Energy-Management Change Drivers -- 1.1.1 Growing Demand for Electricity -- 1.1.2 The Emergence of Renewable Energy Resources -- 1.1.3 The Emergence of Electrified Transportation -- 1.1.4 Deregulation of Electric Power Markets -- 1.1.5 Innovations in Smart Grid Technology -- 1.2 The Need for a Technical Solution -- 1.3 eIoT as an Energy-Management Solution -- 1.4 Scope and Perspective -- 1.5 Book Outline -- 2 eIoT Activates the Grid Periphery -- 2.1 Change Drivers Will Transform Energy Management at the Grid Periphery -- 2.2 The Challenge of Activating the Grid Periphery -- 2.3 Deploying eIoT as a Scalable Energy Management Solution -- 3 The Development of IoT Within Energy Infrastructure -- 3.1 Network-Enabled Physical Devices: Sensors and Actuators -- 3.1.1 Network-Enabled Physical Devices: Overview -- 3.1.2 Sensing and Actuation of Primary Variables in the Transmission System -- 3.1.2.1 Network-Enabled Sensors: SCADA and PMUs -- 3.1.2.2 Network-Enabled Actuators: AGC, AVR, and FACTS -- 3.1.3 Sensing and Actuation of Supply Side SecondaryVariables -- 3.1.3.1 Networked-Enabled Sensors: Wind, Solar, and Natural Gas Resources -- 3.1.3.2 Networked-Enabled Actuators: Wind and Solar Resources -- 3.1.4 Sensing and Actuation of Primary Variables in the Distribution System -- 3.1.4.1 Network-Enabled Sensors: The Emergence of the Smart Meter -- 3.1.4.2 Network-Enabled Actuators: Distribution Automation -- 3.1.5 Sensing and Actuation of Demand-Side SecondaryVariables -- 3.1.5.1 Energy Monitors with Embedded Data Analytics -- 3.1.5.2 Network-Enabled Smart Switches, Outlets, and Lights. , 3.1.5.3 Network-Enabled Heating and Cooling Appliances -- 3.1.5.4 The Electrification Potential of eIoT -- 3.1.5.5 Net-Zero Homes: Electrification of Residential Energy Consumption -- 3.1.5.6 Net-Zero Industry: Electrification of Industrial Energy Consumption -- 3.1.5.7 Connected, Automated, and Electrified Multi-Modal Transportation -- 3.1.6 Network-Enabled Physical Devices: Conclusion -- 3.2 Communication Networks -- 3.2.1 Overview -- 3.2.2 Grid Operator and Utility Networks -- 3.2.2.1 Wired Communications: Power-Line Carriers and Fiber Optics -- 3.2.2.2 SCADA Networks and Wide-Area Monitoring Systems -- 3.2.2.3 LPWAN Commercial Wireless IoT Technologies -- 3.2.2.4 Wireless Smart Utility Network -- 3.2.2.5 eIoT Perspectives on Grid Operator and Utility Networks -- 3.2.3 Commercial Telecommunication Networks -- 3.2.3.1 Cellular Data Networks: 2.5G-GPRS, 3G-GSM, 4G, and LTE -- 3.2.3.2 WiMAX Networks -- 3.2.3.3 eIoT Perspectives on Commercial Telecommunication Networks -- 3.2.4 Local Area Networks -- 3.2.4.1 Wired Ethernet -- 3.2.4.2 WiFi Networks -- 3.2.4.3 Z-Wave Networks -- 3.2.4.4 ZigBee Networks -- 3.2.4.5 Bluetooth Networks -- 3.2.4.6 Industrial Networks -- 3.2.4.7 Perspectives on Local Area Networks -- 3.2.5 IoT Messaging Protocols -- 3.2.5.1 Data Distribution Service (DDS) -- 3.2.5.2 Message Queue Telemetry Transport (MQTT) -- 3.2.5.3 Constrained Application Protocol (CoAP) -- 3.2.5.4 eXtensible Messaging and Presence Protocol (XMPP) -- 3.2.5.5 Advanced Message Queuing Protocol (AMQP) -- 3.3 Distributed Control and Decision Making -- 3.4 Architectures and Standards -- 3.5 Socio-Technical Implications of eIoT -- 3.5.1 eIoT Privacy -- 3.5.2 eIoT Cybersecurity -- 4 Transactive Energy Applications of eIoT -- 4.1 Transactive Energy -- 4.2 Potential eIoT Energy-Management Use Cases -- 4.2.1 An eIoT Transactive Energy Aggregation Use Case. , 4.2.2 An eIoT Economic Demand Response in Wholesale Electricity Markets Use Case -- 4.3 Applications for Utilities and Distribution System Operators -- 4.4 Customer Applications -- 4.4.1 Industrial Applications -- 4.4.2 Commercial Applications -- 4.4.3 Residential Applications -- 5 eIoT Transforms the Future Electric Grid -- 5.1 Conclusions -- 5.1.1 eIoT Will Become Ubiquitous -- 5.1.2 eIoT Will Enable New Automated Energy-Management Platforms -- 5.1.3 eIoT Will Enable Distributed Techno-Economic Decision Making -- 5.2 Challenges and Opportunities -- 5.2.1 The Convergence of Cyber, Physical, and Economic Performance -- 5.2.2 Re-envisioning the Strategic Business Model for the Utility of the Future -- References -- Index.

Additional Edition: Print version: Muhanji, Steffi O. EIoT Cham : Springer International Publishing AG,c2019 ISBN 9783030104269

Language: English

Subjects: Engineering

Keywords: Electronic books.

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Format: 1 online resource (252 pages)

Edition: 1st ed.

ISBN: 9783031595158

Series Statement: Studies in Energy, Resource and Environmental Economics Series

Note: Intro -- Acknowledgments -- Contents -- Contributors -- Introduction -- 1 Geopolitics of the Energy Transition -- 2 The Emerging Role of Hydrogen in the Geopolitics of the Global Energy Transition -- 3 The Case of Europe in the Emerging Geopolitics of Hydrogen -- 4 Europe's Domestic Hydrogen Politics -- 5 External Dimensions of the European Green Deal and the Role of Hydrogen -- 6 Understanding Europe's Role in the Emerging Geopolitics of Hydrogen: The Contribution of This Volume -- References -- The EU in the Global Hydrogen Race: Bringing Together Climate Action, Energy Security, and Industrial Policy -- 1 Introduction -- 2 The EU's Strategic Vision for a Hydrogen Economy -- 3 Policies for Domestic Hydrogen Development -- 3.1 Research and Innovation -- 3.2 Regulation -- 3.3 Investment Support and Production Subsidies -- 4 External Dimensions of EU Hydrogen Policy -- 4.1 Multilateral Governance -- 4.2 Bilateral Hydrogen Cooperation Within EU Climate and Energy Diplomacy -- 4.3 Cross-Border Hydrogen Trade -- 4.4 Investing in the Hydrogen Economy in Third Countries -- 4.5 International Repercussions of EU Hydrogen Policies -- 5 Conclusion -- References -- Germany's Hydrogen Strategy: Securing Industrial Leadership in a Carbon-Neutral Economy -- 1 Introduction -- 2 Energiewende as Industrial Modernization Strategy: The Emerging Role of Hydrogen -- 3 Germany's Outward-Oriented Hydrogen Strategy -- 3.1 From Energy Partnerships to Hydrogen Partnerships -- 3.2 Multilateral Engagement -- 3.3 Promoting International Hydrogen Supply Chains -- 3.4 International Cooperation in Hydrogen-Related Research -- 3.5 Capacity Building and Skill Development -- 3.6 Promoting a Sustainable Hydrogen Economy -- 4 Conclusion -- Annex -- References -- France's Hydrogen Strategy: Focusing on Domestic Hydrogen Production to Decarbonise Industry and Mobility. , 1 Introduction -- 2 The French Hydrogen Economy Today -- 3 The Role of Hydrogen in French Climate and Energy Policy -- 4 Hydrogen Strategies in France: Main Objectives and Implementation -- 4.1 Three Government Priorities for 2030 and Several French Companies' Strategies -- 4.2 Strategies Formulated by French Regions -- 4.3 Elements on Infrastructure and Cross-border Trade -- 5 External Dimensions of Hydrogen Development in France -- 5.1 Favourable Technical and Political Conditions for France to Become a Hydrogen Exporter and a European Hub -- 5.2 International Perspectives in French Policy Plans -- 5.3 French Hydrogen Diplomacy at the EU Level -- 5.4 French Diplomacy on the International Stage -- 6 Conclusion -- References -- International Dimension of the Polish Hydrogen Strategy. Conditions and Potential for Future Development -- 1 Introduction -- 2 Polish Hydrogen Economy-State of Play, Potential and Challenges -- 3 Polish Hydrogen Strategy-Key Information -- 4 International Dimensions of the Polish Hydrogen Strategy -- 5 Hydrogen in the Context of a Broader Polish Approach to International Energy Security -- 6 Conclusions -- References -- Hydrogen Affairs in Hungary's Politically Confined Ambition -- 1 Introduction -- 2 Domestic Drivers: Enchantment with Nuclear, Natural Gas, and Solar PV -- 3 International Approach -- 4 Conclusion -- References -- Spain's Hydrogen Ambition: Between Reindustrialisation and Export-Led Energy Integration with the EU -- 1 Introduction -- 2 Domestic Development of Hydrogen -- 2.1 A Decentralised Hydrogen Strategy -- 2.2 Leading Sectors: Refining, Fertilisers, Steel and Synthetic Fuels -- 2.3 Technological Development, R+D+I and Professional Skills -- 3 External Dimension of Hydrogen in Spain -- 3.1 The Role of Exports and the Iberian Peninsula as a Hub for Hydrogen Trade. , 3.2 Infrastructure: Hydrogen as a Driver for Greater Energy Integration -- 3.3 Regulatory Diplomacy -- 3.4 Allies and Competitors in the Hydrogen Economy -- 4 Conclusions -- References -- Italian Hydrogen Policy: Drivers, Constraints and Recent Developments -- 1 Hydrogen in Italy: In Search of a National Strategy -- 1.1 Overview and Comparative Advantages -- 1.2 Towards a Hydrogen Policy: Drivers and Key Pillars -- 2 The Role of National Industrial Actors -- 3 The International Dimension of Italian Hydrogen Policy: The Hub Concept and Beyond -- 3.1 Political Dialogue, Research and Innovation -- 3.2 Supply Chain Development and Overseas Financing -- 4 Conclusions -- References -- Hydrogen Policy in the Netherlands: Laying the Foundations for a Scalable Hydrogen Value Chain -- 1 Introduction -- 2 The Position of the Netherlands in the Emerging Low-Carbon Hydrogen Economy -- 2.1 Energy Hub -- 2.2 Industry -- 2.3 North Sea -- 2.4 Gas Legacy Assets -- 3 National Hydrogen Strategy and Policy Initiatives -- 3.1 Cluster-Based Energy Strategy -- 3.2 Prioritized End-Use Sectors -- 3.3 The Role of Different Forms of Hydrogen Production -- 4 International Approach -- 4.1 Bilateral Partnerships -- 4.2 Multilateral Partnerships and Political Dialogue -- 4.3 Shaping Hydrogen Infrastructure -- 4.4 Anticipating the Stages of Development in Organising the Low-Carbon Hydrogen Economy -- 5 More Developments in 2023 -- 6 Conclusions -- References -- Hydrogen Strategy of Sweden: Unpacking the Multiple Drivers and Potential Barriers to Hydrogen Development -- 1 Introduction -- 2 Domestic Hydrogen Development in Sweden -- 2.1 The Swedish Energy Mix and Sources of Emissions -- 2.2 Developing a Swedish Hydrogen Strategy -- 2.3 The Swedish Government as a Driver of Hydrogen Development -- 2.4 Industrial Interests in Hydrogen Development. , 2.5 Low-Carbon Electricity Mix and Different Bidding Zones -- 2.6 Lack of Gas Infrastructure and Natural Storage for Hydrogen -- 2.7 Summary of Opportunities and Trade-Offs -- 3 External Dimension of Hydrogen Development in Sweden -- 3.1 Strategic Objectives of the External Hydrogen Dimension in Sweden -- 3.2 Lobbying for Favorable EU Hydrogen Standards -- 3.3 External Actions of the Swedish Industry -- 4 Conclusion -- References -- Norway's Hydrogen Strategy: Unveiling Green Opportunities and Blue Export Ambitions -- 1 Background and Introduction -- 2 Norway's Hydrogen Strategy: Internal Dimension -- 2.1 Strategy and Policies -- 2.2 Funding Activities and Challenges -- 3 Norway's Hydrogen Strategy: External Dimension -- 3.1 The EU and Norway -- 3.2 Private Sector Involvement -- 3.3 International Policy Dimensions -- 3.4 International Markets, Financing, Capacity Development and Challenges -- 4 Conclusions -- References -- The Geopolitics of Hydrogen in Europe: The Interplay between EU and Member State Policies -- 1 Geopolitical Challenges of Hydrogen in the EU -- 2 Domestic Politics and Energy Policy Legacies -- 3 Competing Hydrogen Technology Pathways in Europe -- 4 Prioritizing Different Types of Hydrogen Use in the EU -- 5 Renewable Energy Deployment and Hydrogen: Up to Speed? -- 6 Funding Hydrogen Policy in the EU: Up to the Task? -- 7 The Politics of Connectivity: Hydrogen Infrastructure in the EU -- 8 The Politics of International Hydrogen Trade -- 9 European Hydrogen Politics: The Art of the Possible -- 10 The EU in the Global Geopolitics of Hydrogen -- Literature.

Additional Edition: Print version: Quitzow, Rainer The Geopolitics of Hydrogen Cham : Springer,c2024 ISBN 9783031595141

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Note: Intro -- Foreword -- Preface -- Contents -- Part I Laboratory Structure -- 1 Sustainability Complex Network -- Introduction -- The Small-World Complex Network -- The Sustainability Complex Network -- From a Small to Large Networks -- Regular Graph -- Random Graph -- From Unweighted to Weighted SCN -- Conclusions and Perspectives -- References -- Part II The Blue Planet and the Ocean Sustainable Economy -- 2 Routes to Ocean Sustainability and Blue Prosperity in a Changing World: Guiding Principles and Open Challenges -- Introduction -- Blue Economy -- Ecosystem Services -- Integrating Blue Economy and Ecosystem -- Economy for a Full World -- Sustainability -- Ocean Under Multiple Threats -- Managing the Last Commons -- Concluding Remarks -- References -- Part III Food Security and the Health of the Planet and Its Inhabitants -- 3 Sustainability, Agricultural Production, Science and Technology -- References -- 4 Liver and Nutrition -- References -- Part IV Climate and Environmental Changes -- 5 Climate Modeling of the Anthropocene -- Introduction -- The Basic Structure of Today's CSMs -- The Process of Producing Twenty-First Century Climate Change Projections and the Assessment of Related Uncertainties -- The Need and Challenge of Including an Interactive Human Component in Climate Models -- References -- Part V The New Data Science for Sustainability and Human Ecology -- 6 Quantitative Human Ecology: Data, Models and Challenges for Sustainability -- Introduction -- Conceptual Models -- Data-Driven Computational Models: Network Science -- Machine Learning -- Challenges -- References -- 7 Computations for Sustainability -- Introduction -- Mathematics for Sustainability -- Real-Life Applications -- Enhancement of Computational Performance -- Conclusions -- References -- Part VI Energy Transition and Industrial Product Chains. , 8 Sustainability in the Energy System and in the Industrial System -- The Industrial System and the Energy System -- "Fuel and Engine" of all Human Activities -- A Brief Historical View -- Recent (R)evolutions -- Central Role of the Human Element in Sustainability -- Current Status of the Industrial System and the Energy System -- A Critical View on Current Data -- The Urgent Need for a Transition -- Implementing the Transition -- Measurement: Quantitative Indicators -- Education: Communicating the Industry-Energy Transition -- Key Enabling Technologies for the Transition -- Economics of the Transition -- Policy and Regulations -- Conclusions -- References -- Part VII Sustainability Frames, Social Equity and the Right to Sustainability -- 9 Framing Sustainability -- Sustainability in Frames -- Sustainability Frames: Very Weak, Weak, Strong, Very Strong -- The Very Weak Sustainability -- The Weak Sustainability -- The Strong Sustainability -- The Very Strong Sustainability -- In Summary: The Distinctive Elements of the Sustainability Frames -- References -- 10 Natural Parks and Sustainable Development: A Theoretical Study -- Introduction -- Natural Parks and Sustainable Development -- Park Supplying Goods: Searching for a Taxonomy -- Governing Collective Goods: The Natural Park as a Place-Based Institution -- Conclusions -- References -- 11 The 'Position' of Social Sciences in Sustainability Issue. The Emblematic Case of Energy Transition -- References -- 12 The Law of Sustainability -- Introduction -- The Legal Framework on Sustainability -- The UN Development Goals -- Climate and Corporations -- Enforcing Sustainable Obligations from Below -- Quantifying the Law? De-quantifying the SDGs? -- The Dark Side of Numbers -- What Law? -- What to Do? -- Part VIII Protection of the Earth Habitats with Space Tools. , 13 Protection of the Earth Habitats with Space Tools -- Space Weather -- Minor Bodies of the Solar System -- Space is Really Interdisciplinary -- The Laboratory for Quantitative Sustainability -- Reference -- Bibliography.

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Series Statement: Science for Sustainable Societies Series

Note: Intro -- Preface: From "Vision 2050" to "New Vision 2050" -- Preface (1): Turning Point of Human History -- Twenty-First Century Is a Special Era -- Various Issues -- Global Warming and Abnormal Weather -- Is Capitalism Sustainable? -- Preface (2): The Latest Report -- Human Race Is Navigating in the Right Direction (1): SDGs -- Human Race Is Navigating in the Right Direction (2): COP21 -- IEA Report -- Japan's Experiences as a Leading Country in Resolving Societal Problems -- Essence of the Era of Saturation -- Saturation of the Population -- Saturation of Man-Made Objects -- Saturation of Minerals -- World in 2050 -- Preface (3): A Society We Are Aiming At -- Creation of a New Society and Values by Resolving Issues -- "Platinum Society": A Vision in the Twenty-First Century -- Essential Factors for a Platinum Society -- A Vision That Can be Realized -- Preface (4): Image of a Platinum Society Has Begun to Appear -- Creative Demand -- Low-Carbon Society -- Energy-Creating Houses and Zero-Energy Buildings -- From Eco-Cars, Eco-Factories, and Cars to Cars, and Zero CO2 -- Diversifying Means of Transportation -- Energy Conservation Is the Best Policy -- Urban Mines -- Renewable Energy -- Japan Will Become a Resource Self-Sufficient Society -- The World Will Become a Sustainable Recycling-Oriented Society -- Harmony with Nature -- Macro-Level Viewpoint of Harmony with Nature -- Health Support and Self-Reliance Support Are Important Industries -- Participation of Active Seniors Is Indispensable -- Various Options -- Free Participation -- Education of Information Technology Nurtures the Next Generation -- Society with Employment -- Society Where Children Will Be Born -- Knowledge Structuring Will Lead to Solutions -- How to Expand and Develop More Successful Examples -- Challenging the Issue Through Knowledge Structuring and Action. , Innovations from Mega-Cities -- Viable Business Ensures Sustainability -- A Society of Lifelong Learning -- Developed Countries Can Achieve Economic Growth -- GDP and IWI -- Platinum Industry and Economic Growth -- Developing Countries Aim at a Platinum Society Together -- Social Disparity and Social Security, the State and the Market -- A System for Innovations -- Twenty-First Century Is a Turning Point -- Platinum Society Network -- References -- Contents -- Chapter 1: The Message in "Vision 2050" -- 1.1 Behind the Birth of Vision 2050 -- 1.1.1 The Need for a "Macro" Vision -- 1.1.2 An Affluent Lifestyle for All -- 1.1.3 Why a Low-Carbon Society? -- 1.1.4 The Threat of Global Warming -- 1.2 What Is Vision 2050? -- 1.2.1 The Vision for 2050 -- 1.2.2 A Happy Low-Carbon Society Is Achievable -- 1.2.3 Saturation of Man-Made Objects and the Material-­Circulating System -- 1.2.4 Tripling Energy Efficiency -- 1.2.5 Doubling the Amount of Renewable Energy -- 1.2.6 Increases in Both Comfort and Economic Performance -- 1.2.7 Premises Consequent on Being a Realistic Vision -- Chapter 2: Progress on Vision 2050 Since 1995 -- 2.1 Saturation of Man-Made Objects and the Material-­Circulating System -- 2.1.1 Saturation of Population -- 2.1.2 Saturation of Man-Made Objects -- 2.1.3 Saturated Demand for Substances and Materials: Cement -- 2.1.4 Saturated Demand for Substances and Materials: Iron -- 2.1.5 Hope for a Circulating Society -- 2.2 Energy Saving and Renewable Energy -- 2.2.1 Further Development Achieved in Energy Saving -- 2.2.2 Putting Renewable Energy at the Core of Energy Investments -- 2.3 Vision 2050 as a Happy Vision -- 2.3.1 The Industrial Structure of Japan as a "Leading Country in Resolving Societal Problems" and Energy -- 2.3.2 Certainly Japan Led the World -- 2.3.3 The World Is Making Progress toward Achieving Vision 2050 -- Bibliography. , Chapter 3: Technology to Support Low-Carbon Society (Using Energy) -- 3.1 Direction of Improvement in Energy Efficiency -- 3.1.1 "Daily Living" and "Monozukuri" -- 3.2 Low Carbon Technologies in the Transportation Sector -- 3.2.1 Shipment Does Not Consume Energy? -- 3.2.2 Energy-Efficient Cars Appear One after Another -- 3.2.3 Car Energy Efficiency Increases Eightfold -- 3.2.4 A Rich Car Life with Diverse Eco Cars -- 3.2.5 Modal Shift in Movement -- 3.3 Low Carbon Technologies in the Home and Business Sectors -- 3.3.1 Promotion of Energy Saving Is Economically Advantageous -- 3.3.2 Energy Conservation Will Be a Business Opportunity -- 3.3.3 Household Energy Consumption Is Consolidated into Electricity -- 3.3.4 Eco Houses Are Also Friendly to Their Occupants -- 3.3.5 The Latest Heat Pump Situation -- 3.3.6 Domestic Fuel Cells Packed with Japanese Technologies -- 3.3.7 Globalize Japanese Environmental Technologies -- 3.4 Low-Carbon Technologies for Monozukuri -- 3.4.1 Shift from Blast Furnaces to Electric Furnaces -- 3.4.2 Aluminum Is an Excellent Material in Terms of Recycling -- 3.4.3 Achieving Material Cycling of Rare Metals -- 3.4.4 Expectations for Dissemination of Industrial Heat Pumps -- Bibliography -- Chapter 4: Technology to Support Low-Carbon Society (Utilizing Energy) -- 4.1 Future Image of Renewable Energy -- 4.1.1 Rethinking the Value of Renewable Energy -- 4.1.2 The Future Image of Solar Cells and Storage Batteries -- 4.1.3 Importance of Balance Between Future Cost and Investment -- 4.1.4 Which Storage Battery Will Be Playing the Leading Role in 2050? -- 4.1.5 Promising Markets Where Various Uses Can Be Considered -- 4.1.6 Dissemination of Hydropower Generation by Region -- 4.1.7 The Potential of Biomass -- 4.1.8 Hydrogen as a Partner of Renewable Energy -- 4.2 Innovations Emerging from Theory and IT. , 4.2.1 Pursuing Efficiency to the Utmost Limit -- 4.2.2 Enhance Efficiency with an Energy Management System -- 4.2.3 Japan Should Compete with High-Added-Value Items -- 4.2.4 Increased Sophistication of Demand Forecasting by Utilizing Big Data -- 4.2.5 The Possibility of Carbon Pricing -- Bibliography -- Chapter 5: Low-Carbon Society in 2050 -- 5.1 Low Carbon Power Supply Systems in 2050 -- 5.1.1 Means to Achieve Low Carbonization -- 5.1.2 80% Reduction and Power Generation Costs -- 5.1.3 Consideration of the Best Power Supply Configuration -- 5.2 Reducing Carbon in Major Fields -- 5.2.1 Value-Added Industry and Low Carbon -- 5.2.2 The Ideal State of the Steel Industry -- 5.3 Reducing CO2 Emissions by 80% Across Japan -- 5.3.1 Low Carbonization by Sector in 2050 -- 5.3.2 Value-Added by Industry and CO2 Emissions in 2050 -- 5.3.3 Image of CO2 Emissions and Changes in GDP in all Industries -- Chapter 6: Platinum Industry and a New Society -- 6.1 What Is a Platinum Society? -- 6.1.1 Per Capita GDP and Average Life Expectancy -- 6.1.2 From Quantitative Sufficiency to Qualitative Sufficiency -- 6.1.3 An Island (Ama-cho) that Increased the Number of Children Attending School Despite a Declining Birthrate -- 6.1.4 Contributing to Lowering Carbon in Asia from Actual Experiences (Kitakyushu) -- 6.1.5 Leadership that Achieved a Miracle (Yanedan) -- 6.1.6 Realizing a Vision in a Megalopolis (Futakotamagawa) -- 6.2 Towards Becoming a Nation Self-Sufficient in Resources -- 6.2.1 Making a Self-Sufficiency Rate of 70% a Reality with Vision 2050 -- 6.2.2 A Scenario for Reviving Forestry -- 6.3 Coexisting in Harmony with Beautiful Nature -- 6.3.1 A World that Is Comfortable for All Living Things -- 6.3.2 Initiatives by Corporations for Living in Harmony with Nature -- 6.4 Good Health and Self-Reliance for a Fulfilling Life. , 6.4.1 The Wisdom of Seniors Is a Social Resource -- 6.4.2 Making Use of the Knowledge and Experience of Seniors for the Next Generation -- 6.5 Diverse Options and Freedom of Participation -- 6.5.1 Why Are Bonds Being Sought After Now? -- 6.5.2 Freedom of Mobility Induces Changes to Work Styles -- 6.5.3 Spread of Multi-habitation -- 6.5.4 Tokyo Work Styles and Countermeasures for Declining Birthrates -- 6.6 New Industries Created in a Platinum Society -- 6.6.1 Marunouchi Platinum University - Thinking About Regional Issues in a Big City -- 6.6.2 Developing Human Resources for Realizing the Platinum Society -- 6.6.3 Education Changing Through ICT -- 6.6.4 Adult Education as a New Industry -- 6.6.5 Developing Leaders Who can Carve Out a Path to a New Era -- 6.6.6 Questioning Anew the Importance of Education -- 6.7 The Platinum Society Becomes More Visible -- 6.7.1 How to Promote a Platinum Society -- 6.7.2 The Platinum Network Society and the Platinum Vision Award -- 6.7.3 Creating the Platinum Society Handbook -- 6.8 The Platinum Society and Vision 2050 -- Bibliography -- Interview -- Interview 1: Toyota Environmental Challenge 2050 -- Challenges Unachievable Following the Lines Laid Before -- The Impact of Climate Change -- "Let's Do What We Have to Do." -- Parts Manufacturers Have a Major Presence -- Mid-To-Long-Term Targets for Clearing Regulations -- Interview 2: Regional Revitalization and New Work Styles -- Local Activation for Stronger Competitiveness -- Japanese Factories Are Competitive -- Relocation of Some Head Office Functions, 3.2 Times More Children -- Retirees Teaching Science to Young Children -- Interview 3: Considering Ways to Solve Social Problems -- There Is Much Room for Innovation of the Social System -- The Notion that a Decline in the Population Means the Economy will Falter Is Faulty. , It Is Innovation for Being Used at the Site.

Additional Edition: Print version: Komiyama, Hiroshi New Vision 2050 Tokyo : Springer Japan,c2018 ISBN 9784431566229

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Note: Intro -- Foreword I -- Foreword II -- Foreword III -- Foreword IV -- Foreword V -- Preface I -- Preface II -- Acknowledgements -- Notes from the book -- Contents -- List of Figures -- List of Tables -- Sustainable Energy for All -- 1 Energy and Sustainable Development -- 1.1 United Nations Sustainability Energy for All (SE4A) Agenda -- 1.2 Sustainable Energy for All in Africa -- 1.2.1 Sustainable Energy for All in Kenya -- 1.2.2 Sustainable Energy for All in Uganda -- 1.2.3 Sustainable Energy for All in South Africa -- 1.2.4 Sustainable Energy for All in Botswana -- 1.2.5 Sustainable Energy for All in Europe -- 1.3 Defining Access to Energy -- 1.4 Distributed Renewable Energy: A Key Leverage Towards Sustainable Energy for All (SE4A) -- 1.5 Sustainable Product-Service Systems Applied to Distributed Renewable Energy: An Introduction -- References -- 2 Distributed/Decentralised Renewable Energy Systems -- 2.1 Distributed/Decentralised Renewable Energy: Sustainability -- 2.2 Distributed/Decentralised Renewable Energy Systems: Structures and Types -- 2.3 Renewable Energy Systems Types -- 2.3.1 Solar Energy -- 2.3.2 Wind Energy -- 2.3.3 Hydro Energy -- 2.3.4 Biomass Energy -- 2.3.5 Geothermal Energy -- 2.4 Is Renewable Energy Zero Impact? -- 2.5 Barriers to Distributed/Decentralised Renewable Energy Systems -- References -- 3 Sustainable Product-Service System (S.PSS) -- 3.1 S.PSS: An Introduction and Definition -- 3.2 S.PSS Types -- 3.2.1 Product-Oriented S.PSS: Adding Value to the Product Life Cycle (Type I) -- 3.2.2 Use-Oriented S.PSS: Offering Enabling Platforms for Customers (Type II) -- 3.2.3 Result-Oriented S.PSS: Offering Final Results to Customers (Type III) -- 3.3 S.PSS Sustainability Benefits -- 3.3.1 S.PSS Environmental Benefits -- 3.3.2 S.PSS Socioethical Benefits -- 3.3.3 S.PSS Economic and Competitive Benefits. , 3.4 S.PSS Barriers and Limits -- 3.4.1 Not All PSSs Are Sustainable -- 3.4.2 Barriers -- References -- 4 Sustainable Product-Service System Applied to Distributed Renewable Energies -- 4.1 Sustainable Product-Service System Applied to Distributed Renewable Energy: A Win-Win Opportunity -- 4.2 Scenario for S.PSS Applied to Distributed Renewable Energy -- 4.2.1 Energy for All in Daily Life (Vision 1) -- 4.2.2 Energise Your Business Without Initial Investment Cost (Vision 2) -- 4.2.3 'Pay x Use' Your Daily Life Products and Energy (Vision 3) -- 4.2.4 Start-up Your Business Paying Per Period for Equipment and Energy (Vision 4) -- 4.3 S.PSS Applied to DRE: Sustainability Potential Benefits -- 4.3.1 Environmental Benefits of S.PSS Applied to DRE -- 4.3.2 Socioethical Benefits of S.PSS Applied to DRE -- 4.3.3 Economic Benefits of S.PSS Applied to DRE -- 4.4 S.PSS Applied to DRE: A New Classification System and 15 Archetypal Models -- 4.4.1 Classification System -- 4.4.2 Archetypal Models of S.PSS Applied to DRE -- 4.5 S.PSS Applied to DRE: Critical Factors -- 4.5.1 Customer -- 4.5.2 Energy System -- 4.5.3 Services -- 4.5.4 Network of Providers -- 4.5.5 Offer -- 4.5.6 Payment Channels -- References -- System Design for Sustainable Energy for All -- 5 Design for Sustainability: An Introduction -- 5.1 Evolution of Design for Sustainability -- 5.2 Product Life Cycle Design or Eco-Design -- 5.3 Design for Eco-Efficient Product-Service Systems -- 5.4 Design for Social Equity and Cohesion -- 5.5 Design for Socio-Technical Transitions -- 5.6 State of the Art of Design for Sustainability -- 5.7 Human-Centred and Universal Design -- References -- 6 System Design For Sustainable Energy For All: A New Role For Designers -- 6.1 System Design for Sustainable Energy for All -- 6.2 SE4A Design Criteria, Guidelines and Examples -- Method and Tools for SD4SEA. , 7 Method and Tools for System Design for Sustainable Energy for All -- 7.1 Method for System Design for Sustainable Energy for All -- 7.2 SD4SEA Tools -- 7.2.1 Sustainability Design Orienting Scenario (SDOS) on S.PSS& -- DRE -- 7.2.2 Strategic Analysis (SA) Template -- 7.2.3 Sustainable Energy for All Idea Tables and Cards -- 7.2.4 E.DRE-Estimator for Distributed Renewable Energy -- 7.2.5 PSS + DRE Innovation Map -- 7.2.6 S.PSS + DRE Design Framework & -- Cards -- 7.2.7 The Energy System Map -- 7.2.8 Innovation Diagram for S.PSS& -- DRE -- 7.2.9 Concept Description Form for S.PSS and DRE -- 7.2.10 Stakeholder Motivation and Sustainability Table -- References -- 8 Practical Examples of Application of SD4SEA Approach/Tools -- 8.1 Introduction -- 8.2 Solar Energy Company, Botswana -- 8.3 SMEs for Energy, Uganda -- 8.4 Summary and Considerations.

Additional Edition: Print version: Vezzoli, Carlo. Designing Sustainable Energy for All Cham : Springer International Publishing AG,c2018 ISBN 9783319702223

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ISBN: 9781780409443

Note: Cover -- Copyright -- Contents -- Acronyms -- Preface and Guide for the Reader -- Acknowledgements -- Part I: Water and Energy - A Human Right -- Chapter 1: Water and energy - for all -- 1.1 Clean Water and Energy for all -- 1.2 Access to Clean Water -- 1.3 Access to Electric Energy -- 1.4 Decoupling Water from Energy with Renewables -- 1.4.1 Renewable energy water footprint -- 1.4.2 Small-scale renewables -- 1.4.3 Providing water using renewables -- 1.4.4 Renewables versus nuclear and fossil energy -- 1.4.5 Electric power cost development -- 1.5 Climate Change Consequences -- 1.6 The Need for Cooperation -- 1.7 Overview of the Book -- 1.8 Further Reading -- Chapter 2: Towards sustainability goals -- 2.1 The UN Sustainable Development Goals -- 2.2 Public Health, Gender Issues and Education -- 2.3 Further Reading -- Chapter 3: The renewable energy revolution -- 3.1 The Global Picture -- 3.2 Off-Grid Developments -- 3.3 Scalability of Renewable Energy -- 3.4 Cost Development of Solar PV and Wind -- 3.5 Solar PV Global Expansion -- 3.6 Wind Power Global Expansion -- 3.7 Geopolitical and Economic Implications -- 3.8 Job Skills to Mount and Operate Small Units -- 3.9 Further Reading -- Part II: Water Technologies -- Chapter 4: Water supply -- 4.1 Pumping -- 4.2 Pumping in Developing Regions -- 4.3 Pumping Characteristics -- 4.4 Pump Efficiency -- 4.5 Components in a Solar PV Pumping System -- 4.5.1 Solar panels -- 4.5.2 Inverters and pump controllers -- 4.6 Further Reading -- Chapter 5: Water treatment -- 5.1 Producing Clean Water -- 5.1.1 Underground water resources -- 5.1.2 Saline water -- 5.1.3 Contaminated water -- 5.1.4 Water treatment technologies -- 5.2 Membrane Separation -- 5.3 Desalination -- 5.3.1 Energy supply for desalination -- 5.3.2 Distillation - thermal methods -- 5.3.3 Reverse osmosis -- 5.3.4 Reverse osmosis membranes. , 5.3.5 Renewable energy for desalination -- 5.3.6 Operation and maintenance issues -- 5.4 Disinfection -- 5.4.1 Disinfection technology -- 5.4.2 UV light disinfection -- 5.5 Further Reading -- Chapter 6: Solar thermal desalination and solar water heating -- 6.1 Solar Still Distillation for Cleaning Water -- 6.2 Solar Water Heating -- 6.3 Further Reading -- Chapter 7: Used water treatment -- 7.1 Main Sources of Used Water -- 7.2 Treatment of Used Water -- 7.2.1 Septic tanks -- 7.2.2 Activated sludge systems -- 7.2.3 Anaerobic digestion -- 7.2.4 Membrane separation -- 7.2.5 Disinfection -- 7.3 Energy Aspects -- 7.4 Further Reading -- Part III: Renewable Energy Technologies -- Chapter 8: Solar PV -- 8.1 Utilising the Sun -- 8.1.1 Irradiance -- 8.1.2 Global horizontal irradiance -- 8.2 Solar PV Characteristic Parameters -- 8.3 Conversion of Sunlight to Electricity -- 8.3.1 Photovoltaic technologies -- 8.3.2 Efficiency of PV modules -- 8.3.3 Temperature dependence -- 8.3.4 Floating PV systems -- 8.3.5 Technology development -- 8.4 Systems of Solar Cells -- 8.5 Energy Requirements for water operations -- 8.6 Further Reading -- Chapter 9: Wind -- 9.1 Basic Properties of Wind Turbine Power -- 9.2 Wind Power Efficiency -- 9.3 Further Reading -- Chapter 10: Handling Variable Production -- 10.1 Intermittent Production Characteristics -- 10.1.1 Capacity factor -- 10.1.2 Load profile -- 10.1.3 Intermittent desalination -- 10.2 Storage of Energy -- 10.2.1 Storage requirements in low-income versus high-income countries -- 10.2.2 Storage technologies -- 10.3 Battery Storage -- 10.3.1 Lead-acid batteries -- 10.3.2 Lithium batteries -- 10.3.3 Saltwater batteries -- 10.3.4 Flow batteries -- 10.4 Battery Parameters -- 10.4.1 Battery capacity -- 10.4.2 Battery sizing -- 10.4.3 Battery classification -- 10.4.4 Battery charge controller -- 10.5 Hydrogen Energy Storage. , 10.5.1 Electrolysis of water -- 10.5.2 Fuel cells -- 10.6 Pumped and Cleaned Water as Storage -- 10.7 Diesel Generators as Backup -- 10.8 Cost of Energy Storage -- 10.9 Further Reading -- Chapter 11: Energy Management Systems -- 11.1 The Role of the Energy Management System -- 11.2 The Loads -- Part IV: Applying Renewable Energy to Water Operations -- Chapter 12: Economy -- 12.1 Cost of Renewables -- 12.1.1 Up-front capital cost versus fuel costs -- 12.1.2 Levelised cost of electricity -- 12.1.3 Levelised cost for solar PV -- 12.1.4 Levelised cost for wind energy -- 12.2 Job Opportunities -- 12.2.1 Job creation in the solar industry -- 12.2.2 Job creation in the wind industry -- 12.3 Financing -- 12.3.1 Funding in rural areas -- 12.3.2 Payment models -- 12.4 Further Reading -- Chapter 13: Land use for energy -- Chapter 14: Water operations using renewables - some cases -- 14.1 Developing Countries Versus High-Income Countries -- 14.2 Irrigation and Water Pumping -- 14.3 Desalination -- 14.3.1 Solar PV desalination installations -- 14.3.2 Wind power desalination installations -- 14.4 Further Reading on Desalination and Renewable Energy -- Part V: The Future -- Chapter 15: Outlook to 2030 and further -- 15.1 Predictions for Renewables -- 15.2 Desalination Research and Development -- 15.3 Soft Issues -- 15.3.1 Education and training -- 15.4 Further Reading -- Appendix 1: Glossary -- Appendix 2: Conversion of Units -- A2.1 Power and Energy -- A2.2 Pressure -- A2.3 Heat Content -- A2.4 Volume, Area and Length -- A2.5 Mass -- A2.6 Concentration -- A2.7 Water Use in Energy Production/Generation -- A2.8 Energy Use in Water Operations -- Bibliography -- Index.

Additional Edition: Print version: Olsson, Gustaf Clean Water Using Solar and Wind London : IWA Publishing,c2018 ISBN 9781780409436

Language: English

Keywords: Electronic books. ; Electronic books. ; Electronic books

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