The Future European Energy System : : Renewable Energy, Flexibility Options and Technological Progress.
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| Place / Publishing House: | Cham : : Springer International Publishing AG,, 2021. {copy}2021. |
| Year of Publication: | 2021 |
| Edition: | 1st ed. |
| Language: | English |
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| Physical Description: | 1 online resource (321 pages) |
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Möst, Dominik. The Future European Energy System : Renewable Energy, Flexibility Options and Technological Progress. 1st ed. Cham : Springer International Publishing AG, 2021. {copy}2021. 1 online resource (321 pages) text txt rdacontent computer c rdamedia online resource cr rdacarrier Intro -- Foreword -- Acknowledgments -- Contents -- Editors and Contributors -- About the Editors -- Contributors -- List of Figures -- List of Tables -- Part IIntroduction, Scenario Description and Model Coupling Approach -- 1 Introduction -- Reference -- 2 Scenario Storyline in Context of Decarbonization Pathways for a Future European Energy System -- 2.1 Introduction -- 2.2 Scenario Definition and General Drivers -- 2.3 Socio-Technical Scenario Framework -- 2.4 Moderate Renewable Energy Source Scenario (Mod-RES) -- 2.5 Centralized versus Decentralized High Renewable Scenario (High-RES) -- 2.5.1 Centralized High-RES Scenario -- 2.5.2 Decentralized High-RES Scenario -- 2.6 Conclusions -- References -- 3 Model Coupling Approach for the Analysis of the Future European Energy System -- 3.1 Introduction -- 3.2 Description of Applied Models -- 3.2.1 ELTRAMOD -- 3.2.2 TIMES-Heat-EU -- 3.2.3 PowerACE -- 3.2.4 FORECAST -- 3.2.5 eLOAD -- 3.2.6 ASTRA -- 3.2.7 TE3 -- 3.2.8 eLCA and sLCA -- 3.2.9 πESA -- 3.3 REFLEX Energy Models System -- References -- Part IITechnological Progress -- 4 Deriving Experience Curves and Implementing Technological Learning in Energy System Models -- 4.1 Introduction -- 4.1.1 History and Concept -- 4.1.2 Key Applications of Experience Curves -- 4.1.3 Key Issues and Drawbacks of Experience Curves -- 4.2 Data Collection and Derivation of Experience Curves -- 4.2.1 Functional Unit and System Boundaries -- 4.2.2 Correction for Currency and Inflation -- 4.2.3 Deriving Experience Curve Parameters -- 4.3 Experience Curves in Energy System Models -- 4.3.1 Model Implementation of Experience Curves -- 4.3.2 Issues with Implementation of Experience Curves in Energy Models -- 4.3.3 Description of Energy Models with Implemented Experience Curves -- 4.4 State-of-the-Art Experience Curves and Modeling Results. 4.4.1 Overview of State-of-the-Art Experience Curves -- 4.4.2 Deployments and Cost Developments of Relevant Technologies -- 4.5 Lessons Learned -- 4.5.1 Methodological Issues -- 4.5.2 Model Implementation Issues -- 4.6 Conclusions -- References -- 5 Electric Vehicle Market Diffusion in Main Non-European Markets -- 5.1 Introduction -- 5.1.1 Motivation -- 5.1.2 Related Research and Research Question -- 5.2 Considering Experience Curves in Market Diffusion Modeling and Scenario Definition -- 5.2.1 The TE3 Model and Implementation of Experience Curves -- 5.2.2 Framework of the Two Analyzed Scenarios for the Main Non-European Car Markets -- 5.3 Results of Key Non-European Countries -- 5.3.1 Effects on Cumulative Battery Capacity and Battery Costs -- 5.3.2 Development of the Car Stock for the Four Main Markets in the Mod-RES and High-RES Scenario -- 5.3.3 Critical Review and Limitations -- 5.4 Summary and Conclusions -- References -- Part IIIDemand Side Flexibility and the Role of Disruptive Technologies -- 6 Future Energy Demand Developments and Demand Side Flexibility in a Decarbonized Centralized Energy System -- 6.1 Introduction -- 6.2 Scenario Assumptions and Model Coupling -- 6.3 Future Energy Demand and CO2 Emissions -- 6.3.1 Decarbonizing the Transport Sector -- 6.3.2 Decarbonizing the Residential and Tertiary Sector -- 6.3.3 Decarbonizing the Industry Sector -- 6.4 The Future Need for Demand Side Flexibility -- 6.5 Conclusions -- References -- 7 Disruptive Demand Side Technologies: Market Shares and Impact on Flexibility in a Decentralized World -- 7.1 Introduction -- 7.1.1 Strategies for Decarbonizing Transport -- 7.1.2 Technologies for Decarbonizing Industry -- 7.1.3 Focus of this Study: Disruptive Technologies with Demand Side Flexibility -- 7.2 Disruptive Technologies with Flexibility Potential. 7.2.1 Photovoltaic Systems and Stationary Batteries -- 7.2.2 Battery Electric Vehicles -- 7.2.3 Hydrogen Electrolysis -- 7.3 Scenario Assumptions and Methodology -- 7.3.1 Scenario Assumptions for High-RES Decentralized -- 7.3.2 Model Coupling Approach -- 7.3.3 Methods Used for Technology Diffusion -- 7.4 Results: Diffusion of Technologies and Energy Demand -- 7.4.1 Installed Battery Capacity -- 7.4.2 Vehicle Fleet Technology Composition and Resulting Energy Demand -- 7.4.3 Radical Process Improvements in Industry and Their Implications for Future Electricity Demand -- 7.5 Impacts of Disruptive Technologies on Demand Side Flexibility -- 7.6 Discussion and Conclusions -- References -- 8 What is the Flexibility Potential in the Tertiary Sector? -- 8.1 Introduction -- 8.1.1 Overview of Demand Side Flexibility Markets -- 8.1.2 Overview of Tertiary Sector and Potential Applications, Regulatory Environment -- 8.2 Data Collection Methodology -- 8.2.1 Research Questions -- 8.2.2 Empirical Survey Introduction -- 8.2.3 Issues Encountered Regarding Empirical Data -- 8.3 Survey Results and Derived Flexibility Potentials -- 8.3.1 Participation Interest in DSM -- 8.3.2 Available Technologies -- 8.3.3 Derived Flexibility Potentials (S-Curve) -- 8.3.4 Lessons Learned and Issues Identified for Modelers -- 8.4 Conclusions and Recommendations for Further Research -- References -- 9 A Techno-Economic Comparison of Demand Side Management with Other Flexibility Options -- 9.1 Introduction -- 9.2 Techno-Economic Characteristics of DSM in Comparison with Other Flexibility Options -- 9.2.1 Technical Characteristics of DSM -- 9.2.2 Activation and Initialization Costs of DSM -- 9.3 Impact of DSM on Other Flexibility Options -- 9.3.1 Framework of the Analysis -- 9.3.2 Impact of DSM on the Operation of Conventional Power Plants and Pump Storage Plants. 9.3.3 Impact of DSM on Imports and Exports -- 9.4 Conclusions -- References -- Part IVFlexibility Options in the Electricity and Heating Sector -- 10 Optimal Energy Portfolios in the Electricity Sector: Trade-Offs and Interplay Between Different Flexibility Options -- 10.1 Introduction -- 10.2 Data Input and Model Coupling -- 10.3 Optimal Investments in Flexibility Options -- 10.3.1 Sector Coupling Technologies -- 10.3.2 Power Plant Mix -- 10.3.3 Storages -- 10.4 Sensitivity Analyses -- 10.4.1 Impact of Limited DSM Potential and Reduced Battery Investment Costs on the Storage Value in the Electricity Market -- 10.4.2 Impact of Higher Shares of Renewable Energy Sources -- 10.5 Levelized Costs of Electricity and CO2 Abatement Costs -- 10.6 Discussion and Conclusion -- References -- 11 Impact of Electricity Market Designs on Investments in Flexibility Options -- 11.1 The European Debate on Electricity Market Design -- 11.2 Research Design -- 11.3 Development of the Conventional Generation Capacities and Wholesale Electricity Prices -- 11.3.1 Mod-RES Scenario -- 11.3.2 High-RES Decentralized Scenario -- 11.3.3 High-RES Centralized Scenario -- 11.4 Impact on Generation Adequacy -- 11.5 Summary and Conclusions -- References -- 12 Optimal Energy Portfolios in the Heating Sector and Flexibility Potentials of Combined-Heat-Power Plants and District Heating Systems -- 12.1 Introduction -- 12.2 TIMES-Heat-EU Model -- 12.3 Developments in the District Heating Sector -- 12.3.1 Scenario Results -- 12.3.2 CO2 Emissions in the Heating Sector -- 12.3.3 Sensitivity Analysis -- 12.4 Conclusion -- References -- Part VAnalysis of the Environmental and Socio-Impacts beyond the Greenhouse Gas Emission Reduction Targets -- 13 Unintended Environmental Impacts at Local and Global Scale-Trade-Offs of a Low-Carbon Electricity System -- 13.1 Introduction. 13.2 Developing the Model Coupling Approach to Identify Environmental Trade-Offs -- 13.2.1 Describing Relevant Input Parameters for the LCA Model in Context of the REFLEX Scenarios -- 13.2.2 Coupling the Results of ELTRAMOD and the LCA Model to Determine Policy Implications -- 13.3 Unintended Environmental Consequences of the European Low-Carbon Electricity System -- 13.3.1 Environmental Impacts at Local Scale and the Challenges for European Member States -- 13.3.2 Resource Depletion in REFLEX Mitigation Scenarios as a Backdrop of Global Trade Uncertainty -- 13.4 Conclusions and Policy Implications -- References -- 14 Assessing Social Impacts in Current and Future Electricity Production in the European Union -- 14.1 Introduction -- 14.2 Method -- 14.2.1 Background to the SOCA Add-on for Social Life Cycle Assessment -- 14.2.2 Establishing the Life Cycle Model for Social Assessment -- 14.2.3 Social Impact Categories -- 14.2.4 Calculation Method -- 14.2.5 Contribution Analysis -- 14.3 Results -- 14.4 Concluding Discussion and Policy Implications -- References -- 15 Spatially Disaggregated Impact Pathway Analysis of Direct Particulate Matter Emissions -- 15.1 Introduction -- 15.2 Description of the Method -- 15.2.1 Emission Scenarios -- 15.2.2 Air Quality Modeling -- 15.2.3 Health Impacts and External Costs -- 15.3 Results -- 15.3.1 Summary and Conclusions -- References -- Part VIConcluding Remarks -- 16 Summary, Conclusion and Recommendations -- 16.1 Summary -- 16.1.1 Electricity Sector -- 16.1.2 Demand Side Sectors -- 16.1.3 Environmental Impacts -- 16.2 Conclusions and Recommendations -- 16.2.1 Electricity Sector -- 16.2.2 Industry Sector -- 16.2.3 Transport Sector -- 16.2.4 Heating Sector -- 16.2.5 Environmental, Social Life Cycle and Health Impact Assessment -- 16.3 Further Aspects and Outlook -- References. Description based on publisher supplied metadata and other sources. Electronic reproduction. Ann Arbor, Michigan : ProQuest Ebook Central, 2024. Available via World Wide Web. Access may be limited to ProQuest Ebook Central affiliated libraries. Electronic books. Schreiber, Steffi. Herbst, Andrea. Jakob, Martin. Martino, Angelo. Poganietz, Witold-Roger. Print version: Möst, Dominik The Future European Energy System Cham : Springer International Publishing AG,c2021 9783030609139 ProQuest (Firm) https://ebookcentral.proquest.com/lib/oeawat/detail.action?docID=6491804 Click to View |
| language |
English |
| format |
eBook |
| author |
Möst, Dominik. |
| spellingShingle |
Möst, Dominik. The Future European Energy System : Renewable Energy, Flexibility Options and Technological Progress. Intro -- Foreword -- Acknowledgments -- Contents -- Editors and Contributors -- About the Editors -- Contributors -- List of Figures -- List of Tables -- Part IIntroduction, Scenario Description and Model Coupling Approach -- 1 Introduction -- Reference -- 2 Scenario Storyline in Context of Decarbonization Pathways for a Future European Energy System -- 2.1 Introduction -- 2.2 Scenario Definition and General Drivers -- 2.3 Socio-Technical Scenario Framework -- 2.4 Moderate Renewable Energy Source Scenario (Mod-RES) -- 2.5 Centralized versus Decentralized High Renewable Scenario (High-RES) -- 2.5.1 Centralized High-RES Scenario -- 2.5.2 Decentralized High-RES Scenario -- 2.6 Conclusions -- References -- 3 Model Coupling Approach for the Analysis of the Future European Energy System -- 3.1 Introduction -- 3.2 Description of Applied Models -- 3.2.1 ELTRAMOD -- 3.2.2 TIMES-Heat-EU -- 3.2.3 PowerACE -- 3.2.4 FORECAST -- 3.2.5 eLOAD -- 3.2.6 ASTRA -- 3.2.7 TE3 -- 3.2.8 eLCA and sLCA -- 3.2.9 πESA -- 3.3 REFLEX Energy Models System -- References -- Part IITechnological Progress -- 4 Deriving Experience Curves and Implementing Technological Learning in Energy System Models -- 4.1 Introduction -- 4.1.1 History and Concept -- 4.1.2 Key Applications of Experience Curves -- 4.1.3 Key Issues and Drawbacks of Experience Curves -- 4.2 Data Collection and Derivation of Experience Curves -- 4.2.1 Functional Unit and System Boundaries -- 4.2.2 Correction for Currency and Inflation -- 4.2.3 Deriving Experience Curve Parameters -- 4.3 Experience Curves in Energy System Models -- 4.3.1 Model Implementation of Experience Curves -- 4.3.2 Issues with Implementation of Experience Curves in Energy Models -- 4.3.3 Description of Energy Models with Implemented Experience Curves -- 4.4 State-of-the-Art Experience Curves and Modeling Results. 4.4.1 Overview of State-of-the-Art Experience Curves -- 4.4.2 Deployments and Cost Developments of Relevant Technologies -- 4.5 Lessons Learned -- 4.5.1 Methodological Issues -- 4.5.2 Model Implementation Issues -- 4.6 Conclusions -- References -- 5 Electric Vehicle Market Diffusion in Main Non-European Markets -- 5.1 Introduction -- 5.1.1 Motivation -- 5.1.2 Related Research and Research Question -- 5.2 Considering Experience Curves in Market Diffusion Modeling and Scenario Definition -- 5.2.1 The TE3 Model and Implementation of Experience Curves -- 5.2.2 Framework of the Two Analyzed Scenarios for the Main Non-European Car Markets -- 5.3 Results of Key Non-European Countries -- 5.3.1 Effects on Cumulative Battery Capacity and Battery Costs -- 5.3.2 Development of the Car Stock for the Four Main Markets in the Mod-RES and High-RES Scenario -- 5.3.3 Critical Review and Limitations -- 5.4 Summary and Conclusions -- References -- Part IIIDemand Side Flexibility and the Role of Disruptive Technologies -- 6 Future Energy Demand Developments and Demand Side Flexibility in a Decarbonized Centralized Energy System -- 6.1 Introduction -- 6.2 Scenario Assumptions and Model Coupling -- 6.3 Future Energy Demand and CO2 Emissions -- 6.3.1 Decarbonizing the Transport Sector -- 6.3.2 Decarbonizing the Residential and Tertiary Sector -- 6.3.3 Decarbonizing the Industry Sector -- 6.4 The Future Need for Demand Side Flexibility -- 6.5 Conclusions -- References -- 7 Disruptive Demand Side Technologies: Market Shares and Impact on Flexibility in a Decentralized World -- 7.1 Introduction -- 7.1.1 Strategies for Decarbonizing Transport -- 7.1.2 Technologies for Decarbonizing Industry -- 7.1.3 Focus of this Study: Disruptive Technologies with Demand Side Flexibility -- 7.2 Disruptive Technologies with Flexibility Potential. 7.2.1 Photovoltaic Systems and Stationary Batteries -- 7.2.2 Battery Electric Vehicles -- 7.2.3 Hydrogen Electrolysis -- 7.3 Scenario Assumptions and Methodology -- 7.3.1 Scenario Assumptions for High-RES Decentralized -- 7.3.2 Model Coupling Approach -- 7.3.3 Methods Used for Technology Diffusion -- 7.4 Results: Diffusion of Technologies and Energy Demand -- 7.4.1 Installed Battery Capacity -- 7.4.2 Vehicle Fleet Technology Composition and Resulting Energy Demand -- 7.4.3 Radical Process Improvements in Industry and Their Implications for Future Electricity Demand -- 7.5 Impacts of Disruptive Technologies on Demand Side Flexibility -- 7.6 Discussion and Conclusions -- References -- 8 What is the Flexibility Potential in the Tertiary Sector? -- 8.1 Introduction -- 8.1.1 Overview of Demand Side Flexibility Markets -- 8.1.2 Overview of Tertiary Sector and Potential Applications, Regulatory Environment -- 8.2 Data Collection Methodology -- 8.2.1 Research Questions -- 8.2.2 Empirical Survey Introduction -- 8.2.3 Issues Encountered Regarding Empirical Data -- 8.3 Survey Results and Derived Flexibility Potentials -- 8.3.1 Participation Interest in DSM -- 8.3.2 Available Technologies -- 8.3.3 Derived Flexibility Potentials (S-Curve) -- 8.3.4 Lessons Learned and Issues Identified for Modelers -- 8.4 Conclusions and Recommendations for Further Research -- References -- 9 A Techno-Economic Comparison of Demand Side Management with Other Flexibility Options -- 9.1 Introduction -- 9.2 Techno-Economic Characteristics of DSM in Comparison with Other Flexibility Options -- 9.2.1 Technical Characteristics of DSM -- 9.2.2 Activation and Initialization Costs of DSM -- 9.3 Impact of DSM on Other Flexibility Options -- 9.3.1 Framework of the Analysis -- 9.3.2 Impact of DSM on the Operation of Conventional Power Plants and Pump Storage Plants. 9.3.3 Impact of DSM on Imports and Exports -- 9.4 Conclusions -- References -- Part IVFlexibility Options in the Electricity and Heating Sector -- 10 Optimal Energy Portfolios in the Electricity Sector: Trade-Offs and Interplay Between Different Flexibility Options -- 10.1 Introduction -- 10.2 Data Input and Model Coupling -- 10.3 Optimal Investments in Flexibility Options -- 10.3.1 Sector Coupling Technologies -- 10.3.2 Power Plant Mix -- 10.3.3 Storages -- 10.4 Sensitivity Analyses -- 10.4.1 Impact of Limited DSM Potential and Reduced Battery Investment Costs on the Storage Value in the Electricity Market -- 10.4.2 Impact of Higher Shares of Renewable Energy Sources -- 10.5 Levelized Costs of Electricity and CO2 Abatement Costs -- 10.6 Discussion and Conclusion -- References -- 11 Impact of Electricity Market Designs on Investments in Flexibility Options -- 11.1 The European Debate on Electricity Market Design -- 11.2 Research Design -- 11.3 Development of the Conventional Generation Capacities and Wholesale Electricity Prices -- 11.3.1 Mod-RES Scenario -- 11.3.2 High-RES Decentralized Scenario -- 11.3.3 High-RES Centralized Scenario -- 11.4 Impact on Generation Adequacy -- 11.5 Summary and Conclusions -- References -- 12 Optimal Energy Portfolios in the Heating Sector and Flexibility Potentials of Combined-Heat-Power Plants and District Heating Systems -- 12.1 Introduction -- 12.2 TIMES-Heat-EU Model -- 12.3 Developments in the District Heating Sector -- 12.3.1 Scenario Results -- 12.3.2 CO2 Emissions in the Heating Sector -- 12.3.3 Sensitivity Analysis -- 12.4 Conclusion -- References -- Part VAnalysis of the Environmental and Socio-Impacts beyond the Greenhouse Gas Emission Reduction Targets -- 13 Unintended Environmental Impacts at Local and Global Scale-Trade-Offs of a Low-Carbon Electricity System -- 13.1 Introduction. 13.2 Developing the Model Coupling Approach to Identify Environmental Trade-Offs -- 13.2.1 Describing Relevant Input Parameters for the LCA Model in Context of the REFLEX Scenarios -- 13.2.2 Coupling the Results of ELTRAMOD and the LCA Model to Determine Policy Implications -- 13.3 Unintended Environmental Consequences of the European Low-Carbon Electricity System -- 13.3.1 Environmental Impacts at Local Scale and the Challenges for European Member States -- 13.3.2 Resource Depletion in REFLEX Mitigation Scenarios as a Backdrop of Global Trade Uncertainty -- 13.4 Conclusions and Policy Implications -- References -- 14 Assessing Social Impacts in Current and Future Electricity Production in the European Union -- 14.1 Introduction -- 14.2 Method -- 14.2.1 Background to the SOCA Add-on for Social Life Cycle Assessment -- 14.2.2 Establishing the Life Cycle Model for Social Assessment -- 14.2.3 Social Impact Categories -- 14.2.4 Calculation Method -- 14.2.5 Contribution Analysis -- 14.3 Results -- 14.4 Concluding Discussion and Policy Implications -- References -- 15 Spatially Disaggregated Impact Pathway Analysis of Direct Particulate Matter Emissions -- 15.1 Introduction -- 15.2 Description of the Method -- 15.2.1 Emission Scenarios -- 15.2.2 Air Quality Modeling -- 15.2.3 Health Impacts and External Costs -- 15.3 Results -- 15.3.1 Summary and Conclusions -- References -- Part VIConcluding Remarks -- 16 Summary, Conclusion and Recommendations -- 16.1 Summary -- 16.1.1 Electricity Sector -- 16.1.2 Demand Side Sectors -- 16.1.3 Environmental Impacts -- 16.2 Conclusions and Recommendations -- 16.2.1 Electricity Sector -- 16.2.2 Industry Sector -- 16.2.3 Transport Sector -- 16.2.4 Heating Sector -- 16.2.5 Environmental, Social Life Cycle and Health Impact Assessment -- 16.3 Further Aspects and Outlook -- References. |
| author_facet |
Möst, Dominik. Schreiber, Steffi. Herbst, Andrea. Jakob, Martin. Martino, Angelo. Poganietz, Witold-Roger. |
| author_variant |
d m dm |
| author2 |
Schreiber, Steffi. Herbst, Andrea. Jakob, Martin. Martino, Angelo. Poganietz, Witold-Roger. |
| author2_variant |
s s ss a h ah m j mj a m am w r p wrp |
| author2_role |
TeilnehmendeR TeilnehmendeR TeilnehmendeR TeilnehmendeR TeilnehmendeR |
| author_sort |
Möst, Dominik. |
| title |
The Future European Energy System : Renewable Energy, Flexibility Options and Technological Progress. |
| title_sub |
Renewable Energy, Flexibility Options and Technological Progress. |
| title_full |
The Future European Energy System : Renewable Energy, Flexibility Options and Technological Progress. |
| title_fullStr |
The Future European Energy System : Renewable Energy, Flexibility Options and Technological Progress. |
| title_full_unstemmed |
The Future European Energy System : Renewable Energy, Flexibility Options and Technological Progress. |
| title_auth |
The Future European Energy System : Renewable Energy, Flexibility Options and Technological Progress. |
| title_new |
The Future European Energy System : |
| title_sort |
the future european energy system : renewable energy, flexibility options and technological progress. |
| publisher |
Springer International Publishing AG, |
| publishDate |
2021 |
| physical |
1 online resource (321 pages) |
| edition |
1st ed. |
| contents |
Intro -- Foreword -- Acknowledgments -- Contents -- Editors and Contributors -- About the Editors -- Contributors -- List of Figures -- List of Tables -- Part IIntroduction, Scenario Description and Model Coupling Approach -- 1 Introduction -- Reference -- 2 Scenario Storyline in Context of Decarbonization Pathways for a Future European Energy System -- 2.1 Introduction -- 2.2 Scenario Definition and General Drivers -- 2.3 Socio-Technical Scenario Framework -- 2.4 Moderate Renewable Energy Source Scenario (Mod-RES) -- 2.5 Centralized versus Decentralized High Renewable Scenario (High-RES) -- 2.5.1 Centralized High-RES Scenario -- 2.5.2 Decentralized High-RES Scenario -- 2.6 Conclusions -- References -- 3 Model Coupling Approach for the Analysis of the Future European Energy System -- 3.1 Introduction -- 3.2 Description of Applied Models -- 3.2.1 ELTRAMOD -- 3.2.2 TIMES-Heat-EU -- 3.2.3 PowerACE -- 3.2.4 FORECAST -- 3.2.5 eLOAD -- 3.2.6 ASTRA -- 3.2.7 TE3 -- 3.2.8 eLCA and sLCA -- 3.2.9 πESA -- 3.3 REFLEX Energy Models System -- References -- Part IITechnological Progress -- 4 Deriving Experience Curves and Implementing Technological Learning in Energy System Models -- 4.1 Introduction -- 4.1.1 History and Concept -- 4.1.2 Key Applications of Experience Curves -- 4.1.3 Key Issues and Drawbacks of Experience Curves -- 4.2 Data Collection and Derivation of Experience Curves -- 4.2.1 Functional Unit and System Boundaries -- 4.2.2 Correction for Currency and Inflation -- 4.2.3 Deriving Experience Curve Parameters -- 4.3 Experience Curves in Energy System Models -- 4.3.1 Model Implementation of Experience Curves -- 4.3.2 Issues with Implementation of Experience Curves in Energy Models -- 4.3.3 Description of Energy Models with Implemented Experience Curves -- 4.4 State-of-the-Art Experience Curves and Modeling Results. 4.4.1 Overview of State-of-the-Art Experience Curves -- 4.4.2 Deployments and Cost Developments of Relevant Technologies -- 4.5 Lessons Learned -- 4.5.1 Methodological Issues -- 4.5.2 Model Implementation Issues -- 4.6 Conclusions -- References -- 5 Electric Vehicle Market Diffusion in Main Non-European Markets -- 5.1 Introduction -- 5.1.1 Motivation -- 5.1.2 Related Research and Research Question -- 5.2 Considering Experience Curves in Market Diffusion Modeling and Scenario Definition -- 5.2.1 The TE3 Model and Implementation of Experience Curves -- 5.2.2 Framework of the Two Analyzed Scenarios for the Main Non-European Car Markets -- 5.3 Results of Key Non-European Countries -- 5.3.1 Effects on Cumulative Battery Capacity and Battery Costs -- 5.3.2 Development of the Car Stock for the Four Main Markets in the Mod-RES and High-RES Scenario -- 5.3.3 Critical Review and Limitations -- 5.4 Summary and Conclusions -- References -- Part IIIDemand Side Flexibility and the Role of Disruptive Technologies -- 6 Future Energy Demand Developments and Demand Side Flexibility in a Decarbonized Centralized Energy System -- 6.1 Introduction -- 6.2 Scenario Assumptions and Model Coupling -- 6.3 Future Energy Demand and CO2 Emissions -- 6.3.1 Decarbonizing the Transport Sector -- 6.3.2 Decarbonizing the Residential and Tertiary Sector -- 6.3.3 Decarbonizing the Industry Sector -- 6.4 The Future Need for Demand Side Flexibility -- 6.5 Conclusions -- References -- 7 Disruptive Demand Side Technologies: Market Shares and Impact on Flexibility in a Decentralized World -- 7.1 Introduction -- 7.1.1 Strategies for Decarbonizing Transport -- 7.1.2 Technologies for Decarbonizing Industry -- 7.1.3 Focus of this Study: Disruptive Technologies with Demand Side Flexibility -- 7.2 Disruptive Technologies with Flexibility Potential. 7.2.1 Photovoltaic Systems and Stationary Batteries -- 7.2.2 Battery Electric Vehicles -- 7.2.3 Hydrogen Electrolysis -- 7.3 Scenario Assumptions and Methodology -- 7.3.1 Scenario Assumptions for High-RES Decentralized -- 7.3.2 Model Coupling Approach -- 7.3.3 Methods Used for Technology Diffusion -- 7.4 Results: Diffusion of Technologies and Energy Demand -- 7.4.1 Installed Battery Capacity -- 7.4.2 Vehicle Fleet Technology Composition and Resulting Energy Demand -- 7.4.3 Radical Process Improvements in Industry and Their Implications for Future Electricity Demand -- 7.5 Impacts of Disruptive Technologies on Demand Side Flexibility -- 7.6 Discussion and Conclusions -- References -- 8 What is the Flexibility Potential in the Tertiary Sector? -- 8.1 Introduction -- 8.1.1 Overview of Demand Side Flexibility Markets -- 8.1.2 Overview of Tertiary Sector and Potential Applications, Regulatory Environment -- 8.2 Data Collection Methodology -- 8.2.1 Research Questions -- 8.2.2 Empirical Survey Introduction -- 8.2.3 Issues Encountered Regarding Empirical Data -- 8.3 Survey Results and Derived Flexibility Potentials -- 8.3.1 Participation Interest in DSM -- 8.3.2 Available Technologies -- 8.3.3 Derived Flexibility Potentials (S-Curve) -- 8.3.4 Lessons Learned and Issues Identified for Modelers -- 8.4 Conclusions and Recommendations for Further Research -- References -- 9 A Techno-Economic Comparison of Demand Side Management with Other Flexibility Options -- 9.1 Introduction -- 9.2 Techno-Economic Characteristics of DSM in Comparison with Other Flexibility Options -- 9.2.1 Technical Characteristics of DSM -- 9.2.2 Activation and Initialization Costs of DSM -- 9.3 Impact of DSM on Other Flexibility Options -- 9.3.1 Framework of the Analysis -- 9.3.2 Impact of DSM on the Operation of Conventional Power Plants and Pump Storage Plants. 9.3.3 Impact of DSM on Imports and Exports -- 9.4 Conclusions -- References -- Part IVFlexibility Options in the Electricity and Heating Sector -- 10 Optimal Energy Portfolios in the Electricity Sector: Trade-Offs and Interplay Between Different Flexibility Options -- 10.1 Introduction -- 10.2 Data Input and Model Coupling -- 10.3 Optimal Investments in Flexibility Options -- 10.3.1 Sector Coupling Technologies -- 10.3.2 Power Plant Mix -- 10.3.3 Storages -- 10.4 Sensitivity Analyses -- 10.4.1 Impact of Limited DSM Potential and Reduced Battery Investment Costs on the Storage Value in the Electricity Market -- 10.4.2 Impact of Higher Shares of Renewable Energy Sources -- 10.5 Levelized Costs of Electricity and CO2 Abatement Costs -- 10.6 Discussion and Conclusion -- References -- 11 Impact of Electricity Market Designs on Investments in Flexibility Options -- 11.1 The European Debate on Electricity Market Design -- 11.2 Research Design -- 11.3 Development of the Conventional Generation Capacities and Wholesale Electricity Prices -- 11.3.1 Mod-RES Scenario -- 11.3.2 High-RES Decentralized Scenario -- 11.3.3 High-RES Centralized Scenario -- 11.4 Impact on Generation Adequacy -- 11.5 Summary and Conclusions -- References -- 12 Optimal Energy Portfolios in the Heating Sector and Flexibility Potentials of Combined-Heat-Power Plants and District Heating Systems -- 12.1 Introduction -- 12.2 TIMES-Heat-EU Model -- 12.3 Developments in the District Heating Sector -- 12.3.1 Scenario Results -- 12.3.2 CO2 Emissions in the Heating Sector -- 12.3.3 Sensitivity Analysis -- 12.4 Conclusion -- References -- Part VAnalysis of the Environmental and Socio-Impacts beyond the Greenhouse Gas Emission Reduction Targets -- 13 Unintended Environmental Impacts at Local and Global Scale-Trade-Offs of a Low-Carbon Electricity System -- 13.1 Introduction. 13.2 Developing the Model Coupling Approach to Identify Environmental Trade-Offs -- 13.2.1 Describing Relevant Input Parameters for the LCA Model in Context of the REFLEX Scenarios -- 13.2.2 Coupling the Results of ELTRAMOD and the LCA Model to Determine Policy Implications -- 13.3 Unintended Environmental Consequences of the European Low-Carbon Electricity System -- 13.3.1 Environmental Impacts at Local Scale and the Challenges for European Member States -- 13.3.2 Resource Depletion in REFLEX Mitigation Scenarios as a Backdrop of Global Trade Uncertainty -- 13.4 Conclusions and Policy Implications -- References -- 14 Assessing Social Impacts in Current and Future Electricity Production in the European Union -- 14.1 Introduction -- 14.2 Method -- 14.2.1 Background to the SOCA Add-on for Social Life Cycle Assessment -- 14.2.2 Establishing the Life Cycle Model for Social Assessment -- 14.2.3 Social Impact Categories -- 14.2.4 Calculation Method -- 14.2.5 Contribution Analysis -- 14.3 Results -- 14.4 Concluding Discussion and Policy Implications -- References -- 15 Spatially Disaggregated Impact Pathway Analysis of Direct Particulate Matter Emissions -- 15.1 Introduction -- 15.2 Description of the Method -- 15.2.1 Emission Scenarios -- 15.2.2 Air Quality Modeling -- 15.2.3 Health Impacts and External Costs -- 15.3 Results -- 15.3.1 Summary and Conclusions -- References -- Part VIConcluding Remarks -- 16 Summary, Conclusion and Recommendations -- 16.1 Summary -- 16.1.1 Electricity Sector -- 16.1.2 Demand Side Sectors -- 16.1.3 Environmental Impacts -- 16.2 Conclusions and Recommendations -- 16.2.1 Electricity Sector -- 16.2.2 Industry Sector -- 16.2.3 Transport Sector -- 16.2.4 Heating Sector -- 16.2.5 Environmental, Social Life Cycle and Health Impact Assessment -- 16.3 Further Aspects and Outlook -- References. |
| isbn |
9783030609146 9783030609139 |
| callnumber-first |
H - Social Science |
| callnumber-subject |
HD - Industries, Land Use, Labor |
| callnumber-label |
HD9502-9502 |
| callnumber-sort |
HD 49502 49502.5 |
| genre |
Electronic books. |
| genre_facet |
Electronic books. |
| url |
https://ebookcentral.proquest.com/lib/oeawat/detail.action?docID=6491804 |
| illustrated |
Not Illustrated |
| oclc_num |
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The Future European Energy System : Renewable Energy, Flexibility Options and Technological Progress. |
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<?xml version="1.0" encoding="UTF-8"?><collection xmlns="http://www.loc.gov/MARC21/slim"><record><leader>12089nam a22004813i 4500</leader><controlfield tag="001">5006491804</controlfield><controlfield tag="003">MiAaPQ</controlfield><controlfield tag="005">20240229073839.0</controlfield><controlfield tag="006">m o d | </controlfield><controlfield tag="007">cr cnu||||||||</controlfield><controlfield tag="008">240229s2021 xx o ||||0 eng d</controlfield><datafield tag="020" ind1=" " ind2=" "><subfield code="a">9783030609146</subfield><subfield code="q">(electronic bk.)</subfield></datafield><datafield tag="020" ind1=" " ind2=" "><subfield code="z">9783030609139</subfield></datafield><datafield tag="035" ind1=" " ind2=" "><subfield code="a">(MiAaPQ)5006491804</subfield></datafield><datafield tag="035" ind1=" " ind2=" "><subfield code="a">(Au-PeEL)EBL6491804</subfield></datafield><datafield tag="035" ind1=" " ind2=" "><subfield code="a">(OCoLC)1240209242</subfield></datafield><datafield tag="040" ind1=" " ind2=" "><subfield code="a">MiAaPQ</subfield><subfield code="b">eng</subfield><subfield code="e">rda</subfield><subfield code="e">pn</subfield><subfield code="c">MiAaPQ</subfield><subfield code="d">MiAaPQ</subfield></datafield><datafield tag="050" ind1=" " ind2="4"><subfield code="a">HD9502-9502.5</subfield></datafield><datafield tag="100" ind1="1" ind2=" "><subfield code="a">Möst, Dominik.</subfield></datafield><datafield tag="245" ind1="1" ind2="4"><subfield code="a">The Future European Energy System :</subfield><subfield code="b">Renewable Energy, Flexibility Options and Technological Progress.</subfield></datafield><datafield tag="250" ind1=" " ind2=" "><subfield code="a">1st ed.</subfield></datafield><datafield tag="264" ind1=" " ind2="1"><subfield code="a">Cham :</subfield><subfield code="b">Springer International Publishing AG,</subfield><subfield code="c">2021.</subfield></datafield><datafield tag="264" ind1=" " ind2="4"><subfield code="c">{copy}2021.</subfield></datafield><datafield tag="300" ind1=" " ind2=" "><subfield code="a">1 online resource (321 pages)</subfield></datafield><datafield tag="336" ind1=" " ind2=" "><subfield code="a">text</subfield><subfield code="b">txt</subfield><subfield code="2">rdacontent</subfield></datafield><datafield tag="337" ind1=" " ind2=" "><subfield code="a">computer</subfield><subfield code="b">c</subfield><subfield code="2">rdamedia</subfield></datafield><datafield tag="338" ind1=" " ind2=" "><subfield code="a">online resource</subfield><subfield code="b">cr</subfield><subfield code="2">rdacarrier</subfield></datafield><datafield tag="505" ind1="0" ind2=" "><subfield code="a">Intro -- Foreword -- Acknowledgments -- Contents -- Editors and Contributors -- About the Editors -- Contributors -- List of Figures -- List of Tables -- Part IIntroduction, Scenario Description and Model Coupling Approach -- 1 Introduction -- Reference -- 2 Scenario Storyline in Context of Decarbonization Pathways for a Future European Energy System -- 2.1 Introduction -- 2.2 Scenario Definition and General Drivers -- 2.3 Socio-Technical Scenario Framework -- 2.4 Moderate Renewable Energy Source Scenario (Mod-RES) -- 2.5 Centralized versus Decentralized High Renewable Scenario (High-RES) -- 2.5.1 Centralized High-RES Scenario -- 2.5.2 Decentralized High-RES Scenario -- 2.6 Conclusions -- References -- 3 Model Coupling Approach for the Analysis of the Future European Energy System -- 3.1 Introduction -- 3.2 Description of Applied Models -- 3.2.1 ELTRAMOD -- 3.2.2 TIMES-Heat-EU -- 3.2.3 PowerACE -- 3.2.4 FORECAST -- 3.2.5 eLOAD -- 3.2.6 ASTRA -- 3.2.7 TE3 -- 3.2.8 eLCA and sLCA -- 3.2.9 πESA -- 3.3 REFLEX Energy Models System -- References -- Part IITechnological Progress -- 4 Deriving Experience Curves and Implementing Technological Learning in Energy System Models -- 4.1 Introduction -- 4.1.1 History and Concept -- 4.1.2 Key Applications of Experience Curves -- 4.1.3 Key Issues and Drawbacks of Experience Curves -- 4.2 Data Collection and Derivation of Experience Curves -- 4.2.1 Functional Unit and System Boundaries -- 4.2.2 Correction for Currency and Inflation -- 4.2.3 Deriving Experience Curve Parameters -- 4.3 Experience Curves in Energy System Models -- 4.3.1 Model Implementation of Experience Curves -- 4.3.2 Issues with Implementation of Experience Curves in Energy Models -- 4.3.3 Description of Energy Models with Implemented Experience Curves -- 4.4 State-of-the-Art Experience Curves and Modeling Results.</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">4.4.1 Overview of State-of-the-Art Experience Curves -- 4.4.2 Deployments and Cost Developments of Relevant Technologies -- 4.5 Lessons Learned -- 4.5.1 Methodological Issues -- 4.5.2 Model Implementation Issues -- 4.6 Conclusions -- References -- 5 Electric Vehicle Market Diffusion in Main Non-European Markets -- 5.1 Introduction -- 5.1.1 Motivation -- 5.1.2 Related Research and Research Question -- 5.2 Considering Experience Curves in Market Diffusion Modeling and Scenario Definition -- 5.2.1 The TE3 Model and Implementation of Experience Curves -- 5.2.2 Framework of the Two Analyzed Scenarios for the Main Non-European Car Markets -- 5.3 Results of Key Non-European Countries -- 5.3.1 Effects on Cumulative Battery Capacity and Battery Costs -- 5.3.2 Development of the Car Stock for the Four Main Markets in the Mod-RES and High-RES Scenario -- 5.3.3 Critical Review and Limitations -- 5.4 Summary and Conclusions -- References -- Part IIIDemand Side Flexibility and the Role of Disruptive Technologies -- 6 Future Energy Demand Developments and Demand Side Flexibility in a Decarbonized Centralized Energy System -- 6.1 Introduction -- 6.2 Scenario Assumptions and Model Coupling -- 6.3 Future Energy Demand and CO2 Emissions -- 6.3.1 Decarbonizing the Transport Sector -- 6.3.2 Decarbonizing the Residential and Tertiary Sector -- 6.3.3 Decarbonizing the Industry Sector -- 6.4 The Future Need for Demand Side Flexibility -- 6.5 Conclusions -- References -- 7 Disruptive Demand Side Technologies: Market Shares and Impact on Flexibility in a Decentralized World -- 7.1 Introduction -- 7.1.1 Strategies for Decarbonizing Transport -- 7.1.2 Technologies for Decarbonizing Industry -- 7.1.3 Focus of this Study: Disruptive Technologies with Demand Side Flexibility -- 7.2 Disruptive Technologies with Flexibility Potential.</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">7.2.1 Photovoltaic Systems and Stationary Batteries -- 7.2.2 Battery Electric Vehicles -- 7.2.3 Hydrogen Electrolysis -- 7.3 Scenario Assumptions and Methodology -- 7.3.1 Scenario Assumptions for High-RES Decentralized -- 7.3.2 Model Coupling Approach -- 7.3.3 Methods Used for Technology Diffusion -- 7.4 Results: Diffusion of Technologies and Energy Demand -- 7.4.1 Installed Battery Capacity -- 7.4.2 Vehicle Fleet Technology Composition and Resulting Energy Demand -- 7.4.3 Radical Process Improvements in Industry and Their Implications for Future Electricity Demand -- 7.5 Impacts of Disruptive Technologies on Demand Side Flexibility -- 7.6 Discussion and Conclusions -- References -- 8 What is the Flexibility Potential in the Tertiary Sector? -- 8.1 Introduction -- 8.1.1 Overview of Demand Side Flexibility Markets -- 8.1.2 Overview of Tertiary Sector and Potential Applications, Regulatory Environment -- 8.2 Data Collection Methodology -- 8.2.1 Research Questions -- 8.2.2 Empirical Survey Introduction -- 8.2.3 Issues Encountered Regarding Empirical Data -- 8.3 Survey Results and Derived Flexibility Potentials -- 8.3.1 Participation Interest in DSM -- 8.3.2 Available Technologies -- 8.3.3 Derived Flexibility Potentials (S-Curve) -- 8.3.4 Lessons Learned and Issues Identified for Modelers -- 8.4 Conclusions and Recommendations for Further Research -- References -- 9 A Techno-Economic Comparison of Demand Side Management with Other Flexibility Options -- 9.1 Introduction -- 9.2 Techno-Economic Characteristics of DSM in Comparison with Other Flexibility Options -- 9.2.1 Technical Characteristics of DSM -- 9.2.2 Activation and Initialization Costs of DSM -- 9.3 Impact of DSM on Other Flexibility Options -- 9.3.1 Framework of the Analysis -- 9.3.2 Impact of DSM on the Operation of Conventional Power Plants and Pump Storage Plants.</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">9.3.3 Impact of DSM on Imports and Exports -- 9.4 Conclusions -- References -- Part IVFlexibility Options in the Electricity and Heating Sector -- 10 Optimal Energy Portfolios in the Electricity Sector: Trade-Offs and Interplay Between Different Flexibility Options -- 10.1 Introduction -- 10.2 Data Input and Model Coupling -- 10.3 Optimal Investments in Flexibility Options -- 10.3.1 Sector Coupling Technologies -- 10.3.2 Power Plant Mix -- 10.3.3 Storages -- 10.4 Sensitivity Analyses -- 10.4.1 Impact of Limited DSM Potential and Reduced Battery Investment Costs on the Storage Value in the Electricity Market -- 10.4.2 Impact of Higher Shares of Renewable Energy Sources -- 10.5 Levelized Costs of Electricity and CO2 Abatement Costs -- 10.6 Discussion and Conclusion -- References -- 11 Impact of Electricity Market Designs on Investments in Flexibility Options -- 11.1 The European Debate on Electricity Market Design -- 11.2 Research Design -- 11.3 Development of the Conventional Generation Capacities and Wholesale Electricity Prices -- 11.3.1 Mod-RES Scenario -- 11.3.2 High-RES Decentralized Scenario -- 11.3.3 High-RES Centralized Scenario -- 11.4 Impact on Generation Adequacy -- 11.5 Summary and Conclusions -- References -- 12 Optimal Energy Portfolios in the Heating Sector and Flexibility Potentials of Combined-Heat-Power Plants and District Heating Systems -- 12.1 Introduction -- 12.2 TIMES-Heat-EU Model -- 12.3 Developments in the District Heating Sector -- 12.3.1 Scenario Results -- 12.3.2 CO2 Emissions in the Heating Sector -- 12.3.3 Sensitivity Analysis -- 12.4 Conclusion -- References -- Part VAnalysis of the Environmental and Socio-Impacts beyond the Greenhouse Gas Emission Reduction Targets -- 13 Unintended Environmental Impacts at Local and Global Scale-Trade-Offs of a Low-Carbon Electricity System -- 13.1 Introduction.</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">13.2 Developing the Model Coupling Approach to Identify Environmental Trade-Offs -- 13.2.1 Describing Relevant Input Parameters for the LCA Model in Context of the REFLEX Scenarios -- 13.2.2 Coupling the Results of ELTRAMOD and the LCA Model to Determine Policy Implications -- 13.3 Unintended Environmental Consequences of the European Low-Carbon Electricity System -- 13.3.1 Environmental Impacts at Local Scale and the Challenges for European Member States -- 13.3.2 Resource Depletion in REFLEX Mitigation Scenarios as a Backdrop of Global Trade Uncertainty -- 13.4 Conclusions and Policy Implications -- References -- 14 Assessing Social Impacts in Current and Future Electricity Production in the European Union -- 14.1 Introduction -- 14.2 Method -- 14.2.1 Background to the SOCA Add-on for Social Life Cycle Assessment -- 14.2.2 Establishing the Life Cycle Model for Social Assessment -- 14.2.3 Social Impact Categories -- 14.2.4 Calculation Method -- 14.2.5 Contribution Analysis -- 14.3 Results -- 14.4 Concluding Discussion and Policy Implications -- References -- 15 Spatially Disaggregated Impact Pathway Analysis of Direct Particulate Matter Emissions -- 15.1 Introduction -- 15.2 Description of the Method -- 15.2.1 Emission Scenarios -- 15.2.2 Air Quality Modeling -- 15.2.3 Health Impacts and External Costs -- 15.3 Results -- 15.3.1 Summary and Conclusions -- References -- Part VIConcluding Remarks -- 16 Summary, Conclusion and Recommendations -- 16.1 Summary -- 16.1.1 Electricity Sector -- 16.1.2 Demand Side Sectors -- 16.1.3 Environmental Impacts -- 16.2 Conclusions and Recommendations -- 16.2.1 Electricity Sector -- 16.2.2 Industry Sector -- 16.2.3 Transport Sector -- 16.2.4 Heating Sector -- 16.2.5 Environmental, Social Life Cycle and Health Impact Assessment -- 16.3 Further Aspects and Outlook -- References.</subfield></datafield><datafield tag="588" ind1=" " ind2=" "><subfield code="a">Description based on publisher supplied metadata and other sources.</subfield></datafield><datafield tag="590" ind1=" " ind2=" "><subfield code="a">Electronic reproduction. Ann Arbor, Michigan : ProQuest Ebook Central, 2024. Available via World Wide Web. Access may be limited to ProQuest Ebook Central affiliated libraries. </subfield></datafield><datafield tag="655" ind1=" " ind2="4"><subfield code="a">Electronic books.</subfield></datafield><datafield tag="700" ind1="1" ind2=" "><subfield code="a">Schreiber, Steffi.</subfield></datafield><datafield tag="700" ind1="1" ind2=" "><subfield code="a">Herbst, Andrea.</subfield></datafield><datafield tag="700" ind1="1" ind2=" "><subfield code="a">Jakob, Martin.</subfield></datafield><datafield tag="700" ind1="1" ind2=" "><subfield code="a">Martino, Angelo.</subfield></datafield><datafield tag="700" ind1="1" ind2=" "><subfield code="a">Poganietz, Witold-Roger.</subfield></datafield><datafield tag="776" ind1="0" ind2="8"><subfield code="i">Print version:</subfield><subfield code="a">Möst, Dominik</subfield><subfield code="t">The Future European Energy System</subfield><subfield code="d">Cham : Springer International Publishing AG,c2021</subfield><subfield code="z">9783030609139</subfield></datafield><datafield tag="797" ind1="2" ind2=" "><subfield code="a">ProQuest (Firm)</subfield></datafield><datafield tag="856" ind1="4" ind2="0"><subfield code="u">https://ebookcentral.proquest.com/lib/oeawat/detail.action?docID=6491804</subfield><subfield code="z">Click to View</subfield></datafield></record></collection> |