Kooperativer Bibliotheksverbund

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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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URL: https://www.vlebooks.com/vleweb/product/openreader?id=none&isbn=9783030058432

URL: lizenzpflichtig

UID:

Format: 1 online resource (LIX, 491 p. 210 illus., 182 illus. in color.)

Edition: 1st ed. 2019.

ISBN: 3-030-05843-3

Content: This open access book presents detailed pathways to achieve 100% renewable energy by 2050, globally and across ten geographical regions. Based on state-of-the-art scenario modelling, it provides the vital missing link between renewable energy targets and the measures needed to achieve them. Bringing together the latest research in climate science, renewable energy technology, employment and resource impacts, the book breaks new ground by covering all the elements essential to achieving the ambitious climate mitigation targets set out in the Paris Climate Agreement. For example, sectoral implementation pathways, with special emphasis on differences between developed and developing countries and regional conditions, provide tools to implement the scenarios globally and domestically. Non-energy greenhouse gas mitigation scenarios define a sustainable pathway for land-use change and the agricultural sector. Furthermore, results of the impact of the scenarios on employment and mineral and resource requirements provide vital insight on economic and resource management implications. The book clearly demonstrates that the goals of the Paris Agreement are achievable and feasible with current technology and are beneficial in economic and employment terms. It is essential reading for anyone with responsibility for implementing renewable energy or climate targets internationally or domestically, including climate policy negotiators, policy-makers at all levels of government, businesses with renewable energy commitments, researchers and the renewable energy industry.

Note: Chapter 1: The scientific status quo of climate change -- Chapter 2: Development of energy markets – past, present and future perspectives -- Chapter 3: 100% renewable energy – the concept -- Chapter 4: Modelling approaches -- Chapter 5: Energy transition – main assumptions (working title) -- Chapter 6: Global Transport – transition concepts -- Chapter 7:Energy Scenario results -- Chapter 8: Non-energy GHG mitigation scenarios -- Chapter 9: Linking Energy Transition and Climate change mitigation -- Chapter 10: Employment projections -- Chapter 11: Requirement of minerals and metals for 100% RE scenarios -- Chapter 12: Discussion, Conclusions and Recommendations. , English

Additional Edition: ISBN 3-030-05842-5

Language: English

DOI: 10.1007/978-3-030-05843-2

UID:

Format: LIX, 491 p. 210 illus., 182 illus. in color. , online resource.

ISBN: 9783030058432

Content: This open access book presents detailed pathways to achieve 100% renewable energy by 2050, globally and across ten geographical regions. Based on state-of-the-art scenario modelling, it provides the vital missing link between renewable energy targets and the measures needed to achieve them. Bringing together the latest research in climate science, renewable energy technology, employment and resource impacts, the book breaks new ground by covering all the elements essential to achieving the ambitious climate mitigation targets set out in the Paris Climate Agreement. For example, sectoral implementation pathways, with special emphasis on differences between developed and developing countries and regional conditions, provide tools to implement the scenarios globally and domestically. Non-energy greenhouse gas mitigation scenarios define a sustainable pathway for land-use change and the agricultural sector. Furthermore, results of the impact of the scenarios on employment and mineral and resource requirements provide vital insight on economic and resource management implications. The book clearly demonstrates that the goals of the Paris Agreement are achievable and feasible with current technology and are beneficial in economic and employment terms. It is essential reading for anyone with responsibility for implementing renewable energy or climate targets internationally or domestically, including climate policy negotiators, policy-makers at all levels of government, businesses with renewable energy commitments, researchers and the renewable energy industry.

Note: Chapter 1: The scientific status quo of climate change -- Chapter 2: Development of energy markets – past, present and future perspectives -- Chapter 3: 100% renewable energy – the concept -- Chapter 4: Modelling approaches -- Chapter 5: Energy transition – main assumptions (working title) -- Chapter 6: Global Transport – transition concepts -- Chapter 7:Energy Scenario results -- Chapter 8: Non-energy GHG mitigation scenarios -- Chapter 9: Linking Energy Transition and Climate change mitigation -- Chapter 10: Employment projections -- Chapter 11: Requirement of minerals and metals for 100% RE scenarios -- Chapter 12: Discussion, Conclusions and Recommendations.

In: Springer eBooks

Additional Edition: Printed edition: ISBN 9783030058425

Additional Edition: Printed edition: ISBN 9783030058449

Language: English

DOI: 10.1007/978-3-030-05843-2

URL: https://doi.org/10.1007/978-3-030-05843-2

UID:

Format: 1 online resource (LIX, 491 p. 210 illus., 182 illus. in color.)

Edition: 1st ed. 2019.

ISBN: 3-030-05843-3

Content: This open access book presents detailed pathways to achieve 100% renewable energy by 2050, globally and across ten geographical regions. Based on state-of-the-art scenario modelling, it provides the vital missing link between renewable energy targets and the measures needed to achieve them. Bringing together the latest research in climate science, renewable energy technology, employment and resource impacts, the book breaks new ground by covering all the elements essential to achieving the ambitious climate mitigation targets set out in the Paris Climate Agreement. For example, sectoral implementation pathways, with special emphasis on differences between developed and developing countries and regional conditions, provide tools to implement the scenarios globally and domestically. Non-energy greenhouse gas mitigation scenarios define a sustainable pathway for land-use change and the agricultural sector. Furthermore, results of the impact of the scenarios on employment and mineral and resource requirements provide vital insight on economic and resource management implications. The book clearly demonstrates that the goals of the Paris Agreement are achievable and feasible with current technology and are beneficial in economic and employment terms. It is essential reading for anyone with responsibility for implementing renewable energy or climate targets internationally or domestically, including climate policy negotiators, policy-makers at all levels of government, businesses with renewable energy commitments, researchers and the renewable energy industry.

Note: Chapter 1: The scientific status quo of climate change -- Chapter 2: Development of energy markets – past, present and future perspectives -- Chapter 3: 100% renewable energy – the concept -- Chapter 4: Modelling approaches -- Chapter 5: Energy transition – main assumptions (working title) -- Chapter 6: Global Transport – transition concepts -- Chapter 7:Energy Scenario results -- Chapter 8: Non-energy GHG mitigation scenarios -- Chapter 9: Linking Energy Transition and Climate change mitigation -- Chapter 10: Employment projections -- Chapter 11: Requirement of minerals and metals for 100% RE scenarios -- Chapter 12: Discussion, Conclusions and Recommendations. , English

Additional Edition: ISBN 3-030-05842-5

Language: English

DOI: 10.1007/978-3-030-05843-2

UID:

Format: 1 online resource (LIX, 491 p. 210 illus., 182 illus. in color.)

Edition: 1st ed. 2019.

ISBN: 3-030-05843-3

Content: This open access book presents detailed pathways to achieve 100% renewable energy by 2050, globally and across ten geographical regions. Based on state-of-the-art scenario modelling, it provides the vital missing link between renewable energy targets and the measures needed to achieve them. Bringing together the latest research in climate science, renewable energy technology, employment and resource impacts, the book breaks new ground by covering all the elements essential to achieving the ambitious climate mitigation targets set out in the Paris Climate Agreement. For example, sectoral implementation pathways, with special emphasis on differences between developed and developing countries and regional conditions, provide tools to implement the scenarios globally and domestically. Non-energy greenhouse gas mitigation scenarios define a sustainable pathway for land-use change and the agricultural sector. Furthermore, results of the impact of the scenarios on employment and mineral and resource requirements provide vital insight on economic and resource management implications. The book clearly demonstrates that the goals of the Paris Agreement are achievable and feasible with current technology and are beneficial in economic and employment terms. It is essential reading for anyone with responsibility for implementing renewable energy or climate targets internationally or domestically, including climate policy negotiators, policy-makers at all levels of government, businesses with renewable energy commitments, researchers and the renewable energy industry.

Note: Chapter 1: The scientific status quo of climate change -- Chapter 2: Development of energy markets – past, present and future perspectives -- Chapter 3: 100% renewable energy – the concept -- Chapter 4: Modelling approaches -- Chapter 5: Energy transition – main assumptions (working title) -- Chapter 6: Global Transport – transition concepts -- Chapter 7:Energy Scenario results -- Chapter 8: Non-energy GHG mitigation scenarios -- Chapter 9: Linking Energy Transition and Climate change mitigation -- Chapter 10: Employment projections -- Chapter 11: Requirement of minerals and metals for 100% RE scenarios -- Chapter 12: Discussion, Conclusions and Recommendations. , English

Additional Edition: ISBN 3-030-05842-5

Language: English

DOI: 10.1007/978-3-030-05843-2

UID:

Format: 1 online resource (LIX, 491 p. 210 illus., 182 illus. in color.)

Edition: 1st ed. 2019.

ISBN: 3-030-05843-3

Content: This open access book presents detailed pathways to achieve 100% renewable energy by 2050, globally and across ten geographical regions. Based on state-of-the-art scenario modelling, it provides the vital missing link between renewable energy targets and the measures needed to achieve them. Bringing together the latest research in climate science, renewable energy technology, employment and resource impacts, the book breaks new ground by covering all the elements essential to achieving the ambitious climate mitigation targets set out in the Paris Climate Agreement. For example, sectoral implementation pathways, with special emphasis on differences between developed and developing countries and regional conditions, provide tools to implement the scenarios globally and domestically. Non-energy greenhouse gas mitigation scenarios define a sustainable pathway for land-use change and the agricultural sector. Furthermore, results of the impact of the scenarios on employment and mineral and resource requirements provide vital insight on economic and resource management implications. The book clearly demonstrates that the goals of the Paris Agreement are achievable and feasible with current technology and are beneficial in economic and employment terms. It is essential reading for anyone with responsibility for implementing renewable energy or climate targets internationally or domestically, including climate policy negotiators, policy-makers at all levels of government, businesses with renewable energy commitments, researchers and the renewable energy industry.

Note: Chapter 1: The scientific status quo of climate change -- Chapter 2: Development of energy markets – past, present and future perspectives -- Chapter 3: 100% renewable energy – the concept -- Chapter 4: Modelling approaches -- Chapter 5: Energy transition – main assumptions (working title) -- Chapter 6: Global Transport – transition concepts -- Chapter 7:Energy Scenario results -- Chapter 8: Non-energy GHG mitigation scenarios -- Chapter 9: Linking Energy Transition and Climate change mitigation -- Chapter 10: Employment projections -- Chapter 11: Requirement of minerals and metals for 100% RE scenarios -- Chapter 12: Discussion, Conclusions and Recommendations. , English

Additional Edition: ISBN 3-030-05842-5

Language: English

DOI: 10.1007/978-3-030-05843-2

UID:

Format: lix, 491 Seiten , Illustrationen, Diagramme

ISBN: 9783030058425

Additional Edition: Erscheint auch als Online-Ausgabe ISBN 978-3-030-05843-2

Language: English

Subjects: General works

Keywords: Klimaabkommen von Paris ; Treibhauseffekt ; Kohlendioxidemission ; Emissionsverringerung ; Energiewirtschaft ; Energieverbrauch ; Energiebedarf ; Klimaschutz ; Umwelt ; Politik ; Erneuerbare Energien ; Klimaänderung ; Umweltwissenschaften ; Erneuerbare Energien ; Prognose

URL: Volltext  (Kostenfrei)