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The Future European Energy System: Renewable Energy, Flexibility Options And Technological Progress

✍ Scribed by Dominik Möst, Steffi Schreiber, Andrea Herbst, Martin Jakob, Angelo Martino, Witold-Roger Poganietz

Publisher
Springer
Year
2021
Tongue
English
Leaves
321
Edition
1st Edition
Category
Library
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✦ Synopsis

This open access book analyzes the transition toward a low-carbon energy system in Europe under the aspects of flexibility and technological progress. By covering the main energy sectors – including the industry, residential, tertiary and transport sector as well as the heating and electricity sector – the analysis assesses flexibility requirements in a cross-sectoral energy system with high shares of renewable energies. The contributing authors – all European energy experts – apply models and tools from various research fields, including techno-economic learning, fundamental energy system modeling, and environmental and social life cycle as well as health impact assessment, to develop an innovative and comprehensive energy models system (EMS). Moreover, the contributions examine renewable penetrations and their contributions to climate change mitigation, and the impacts of available technologies on the energy system. Given its scope, the book appeals to researchers studying energy systems and markets, professionals and policymakers of the energy industry and readers interested in the transformation to a low-carbon energy system in Europe.

✦ Table of Contents

Foreword......Page 5
Acknowledgments......Page 7
Contents......Page 9
About the Editors......Page 11
Contributors......Page 12
List of Figures......Page 15
List of Tables......Page 26
Part IIntroduction, Scenario Description and Model Coupling Approach......Page 29
1 Introduction......Page 30
Reference......Page 34
2.1 Introduction......Page 35
2.2 Scenario Definition and General Drivers......Page 36
2.3 Socio-Technical Scenario Framework......Page 38
2.5 Centralized versus Decentralized High Renewable Scenario (High-RES)......Page 41
2.5.1 Centralized High-RES Scenario......Page 43
2.5.2 Decentralized High-RES Scenario......Page 47
2.6 Conclusions......Page 49
References......Page 50
3.1 Introduction......Page 52
3.2 Description of Applied Models......Page 53
3.2.1 ELTRAMOD......Page 55
3.2.2 TIMES-Heat-EU......Page 56
3.2.3 PowerACE......Page 58
3.2.4 FORECAST......Page 60
3.2.5 eLOAD......Page 62
3.2.6 ASTRA......Page 63
3.2.7 TE3......Page 65
3.2.8 eLCA and sLCA......Page 67
3.2.9 πESA......Page 68
3.3 REFLEX Energy Models System......Page 70
References......Page 74
Part IITechnological Progress......Page 77
4.1.1 History and Concept......Page 78
4.1.2 Key Applications of Experience Curves......Page 80
4.1.3 Key Issues and Drawbacks of Experience Curves......Page 82
4.2 Data Collection and Derivation of Experience Curves......Page 83
4.2.3 Deriving Experience Curve Parameters......Page 84
4.3 Experience Curves in Energy System Models......Page 85
4.3.2 Issues with Implementation of Experience Curves in Energy Models......Page 86
4.3.3 Description of Energy Models with Implemented Experience Curves......Page 87
4.4 State-of-the-Art Experience Curves and Modeling Results......Page 89
4.4.1 Overview of State-of-the-Art Experience Curves......Page 90
4.4.2 Deployments and Cost Developments of Relevant Technologies......Page 91
4.5.1 Methodological Issues......Page 92
4.5.2 Model Implementation Issues......Page 93
References......Page 94
5.1.1 Motivation......Page 97
5.1.2 Related Research and Research Question......Page 98
5.2.1 The TE3 Model and Implementation of Experience Curves......Page 99
5.2.2 Framework of the Two Analyzed Scenarios for the Main Non-European Car Markets......Page 100
5.3.1 Effects on Cumulative Battery Capacity and Battery Costs......Page 104
5.3.2 Development of the Car Stock for the Four Main Markets in the Mod-RES and High-RES Scenario......Page 105
5.3.3 Critical Review and Limitations......Page 107
References......Page 108
Part IIIDemand Side Flexibility and the Role of Disruptive Technologies......Page 111
6 Future Energy Demand Developments and Demand Side Flexibility in a Decarbonized Centralized Energy System......Page 112
6.1 Introduction......Page 113
6.3 Future Energy Demand and CO2 Emissions......Page 114
6.3.1 Decarbonizing the Transport Sector......Page 117
6.3.2 Decarbonizing the Residential and Tertiary Sector......Page 121
6.3.3 Decarbonizing the Industry Sector......Page 124
6.4 The Future Need for Demand Side Flexibility......Page 127
6.5 Conclusions......Page 131
References......Page 132
7.1 Introduction......Page 135
7.1.1 Strategies for Decarbonizing Transport......Page 136
7.1.2 Technologies for Decarbonizing Industry......Page 137
7.1.3 Focus of this Study: Disruptive Technologies with Demand Side Flexibility......Page 138
7.2.2 Battery Electric Vehicles......Page 139
7.2.3 Hydrogen Electrolysis......Page 140
7.3.1 Scenario Assumptions for High-RES Decentralized......Page 141
7.3.2 Model Coupling Approach......Page 142
7.3.3 Methods Used for Technology Diffusion......Page 143
7.4.1 Installed Battery Capacity......Page 144
7.4.2 Vehicle Fleet Technology Composition and Resulting Energy Demand......Page 145
7.5 Impacts of Disruptive Technologies on Demand Side Flexibility......Page 147
7.6 Discussion and Conclusions......Page 152
References......Page 154
8.1.1 Overview of Demand Side Flexibility Markets......Page 157
8.1.2 Overview of Tertiary Sector and Potential Applications, Regulatory Environment......Page 158
8.2.2 Empirical Survey Introduction......Page 160
8.3.1 Participation Interest in DSM......Page 163
8.3.2 Available Technologies......Page 165
8.3.3 Derived Flexibility Potentials (S-Curve)......Page 168
8.3.4 Lessons Learned and Issues Identified for Modelers......Page 170
References......Page 171
9.1 Introduction......Page 174
9.2.1 Technical Characteristics of DSM......Page 176
9.2.2 Activation and Initialization Costs of DSM......Page 179
9.3.1 Framework of the Analysis......Page 184
9.3.2 Impact of DSM on the Operation of Conventional Power Plants and Pump Storage Plants......Page 186
9.3.3 Impact of DSM on Imports and Exports......Page 189
9.4 Conclusions......Page 190
References......Page 191
Part IVFlexibility Options in the Electricity and Heating Sector......Page 193
10.1 Introduction......Page 194
10.2 Data Input and Model Coupling......Page 196
10.3.1 Sector Coupling Technologies......Page 199
10.3.2 Power Plant Mix......Page 201
10.3.3 Storages......Page 203
10.4.1 Impact of Limited DSM Potential and Reduced Battery Investment Costs on the Storage Value in the Electricity Market......Page 205
10.4.2 Impact of Higher Shares of Renewable Energy Sources......Page 208
10.5 Levelized Costs of Electricity and CO2 Abatement Costs......Page 210
10.6 Discussion and Conclusion......Page 212
References......Page 213
11.1 The European Debate on Electricity Market Design......Page 216
11.2 Research Design......Page 218
11.3 Development of the Conventional Generation Capacities and Wholesale Electricity Prices......Page 220
11.3.1 Mod-RES Scenario......Page 228
11.3.2 High-RES Decentralized Scenario......Page 229
11.4 Impact on Generation Adequacy......Page 230
11.5 Summary and Conclusions......Page 231
References......Page 234
12.1 Introduction......Page 236
12.2 TIMES-Heat-EU Model......Page 237
12.3 Developments in the District Heating Sector......Page 239
12.3.1 Scenario Results......Page 240
12.3.2 CO2 Emissions in the Heating Sector......Page 245
12.3.3 Sensitivity Analysis......Page 246
12.4 Conclusion......Page 248
References......Page 250
Part VAnalysis of the Environmental and Socio-Impacts beyond the Greenhouse Gas Emission Reduction Targets......Page 252
13.1 Introduction......Page 253
13.2 Developing the Model Coupling Approach to Identify Environmental Trade-Offs......Page 255
13.2.1 Describing Relevant Input Parameters for the LCA Model in Context of the REFLEX Scenarios......Page 256
13.2.2 Coupling the Results of ELTRAMOD and the LCA Model to Determine Policy Implications......Page 257
13.3 Unintended Environmental Consequences of the European Low-Carbon Electricity System......Page 259
13.3.1 Environmental Impacts at Local Scale and the Challenges for European Member States......Page 260
13.3.2 Resource Depletion in REFLEX Mitigation Scenarios as a Backdrop of Global Trade Uncertainty......Page 262
13.4 Conclusions and Policy Implications......Page 266
References......Page 268
14.1 Introduction......Page 272
14.2.1 Background to the SOCA Add-on for Social Life Cycle Assessment......Page 274
14.2.2 Establishing the Life Cycle Model for Social Assessment......Page 275
14.2.4 Calculation Method......Page 278
14.3 Results......Page 280
14.4 Concluding Discussion and Policy Implications......Page 286
References......Page 287
15.1 Introduction......Page 289
15.2 Description of the Method......Page 290
15.2.1 Emission Scenarios......Page 291
15.2.2 Air Quality Modeling......Page 294
15.2.3 Health Impacts and External Costs......Page 295
15.3 Results......Page 296
15.3.1 Summary and Conclusions......Page 300
References......Page 302
Part VIConcluding Remarks......Page 304
16.1 Summary......Page 305
16.1.1 Electricity Sector......Page 306
16.1.2 Demand Side Sectors......Page 307
16.1.3 Environmental Impacts......Page 308
16.2.1 Electricity Sector......Page 309
16.2.2 Industry Sector......Page 312
16.2.3 Transport Sector......Page 313
16.2.4 Heating Sector......Page 316
16.2.5 Environmental, Social Life Cycle and Health Impact Assessment......Page 318
16.3 Further Aspects and Outlook......Page 319
References......Page 320

✦ Subjects

Natural Resource And Energy Economics

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