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Considering Life Cycle Greenhouse Gas Emissions in Power System Expansion Planning for Europe and North Africa Using Multi-Objective Optimization

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  • Tobias Junne

    (German Aerospace Center (DLR), Department of Energy Systems Analysis, Institute of Networked Energy Systems, 70563 Stuttgart, Germany)

  • Karl-Kiên Cao

    (German Aerospace Center (DLR), Department of Energy Systems Analysis, Institute of Networked Energy Systems, 70563 Stuttgart, Germany)

  • Kim Kira Miskiw

    (German Aerospace Center (DLR), Department of Energy Systems Analysis, Institute of Networked Energy Systems, 70563 Stuttgart, Germany
    Current affiliation: Karlsruhe Institute of Technology, Institute for Industrial Production—Chair of Energy Economics, 76187 Karlsruhe, Germany.)

  • Heidi Hottenroth

    (Institute for Industrial Ecology (INEC), Pforzheim University, 75175 Pforzheim, Germany)

  • Tobias Naegler

    (German Aerospace Center (DLR), Department of Energy Systems Analysis, Institute of Networked Energy Systems, 70563 Stuttgart, Germany)

Abstract

We integrate life cycle indicators for various technologies of an energy system model with high spatiotemporal detail and a focus on Europe and North Africa. Using multi-objective optimization, we calculate a pareto front that allows us to assess the trade-offs between system costs and life cycle greenhouse gas (GHG) emissions of future power systems. Furthermore, we perform environmental ex-post assessments of selected solutions using a broad set of life cycle impact categories. In a system with the least life cycle GHG emissions, the costs would increase by ~63%, thereby reducing life cycle GHG emissions by ~82% compared to the cost-optimal solution. Power systems mitigating a substantial part of life cycle GHG emissions with small increases in system costs show a trend towards a deployment of wind onshore, electricity grid and a decline in photovoltaic plants and Li-ion storage. Further reductions are achieved by the deployment of concentrated solar power, wind offshore and nuclear power but lead to considerably higher costs compared to the cost-optimal solution. Power systems that mitigate life cycle GHG emissions also perform better for most impact categories but have higher ionizing radiation, water use and increased fossil fuel demand driven by nuclear power. This study shows that it is crucial to consider upstream GHG emissions in future assessments, as they represent an inheritable part of total emissions in ambitious energy scenarios that, so far, mainly aim to reduce direct CO 2 emissions.

Suggested Citation

  • Tobias Junne & Karl-Kiên Cao & Kim Kira Miskiw & Heidi Hottenroth & Tobias Naegler, 2021. "Considering Life Cycle Greenhouse Gas Emissions in Power System Expansion Planning for Europe and North Africa Using Multi-Objective Optimization," Energies, MDPI, vol. 14(5), pages 1-26, February.
    • Handle: RePEc:gam:jeners:v:14:y:2021:i:5:p:1301-:d:506948
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    References listed on IDEAS

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    2. Beck, J.-P. & Reinhard, J. & Kamps, K. & Kupka, J. & Derksen, C., 2022. "Model experiments in operational energy system analysis: Power grid focused scenario comparisons," Renewable and Sustainable Energy Reviews, Elsevier, vol. 164(C).
    3. Dahlia Byles & Salman Mohagheghi, 2023. "Sustainable Power Grid Expansion: Life Cycle Assessment, Modeling Approaches, Challenges, and Opportunities," Sustainability, MDPI, vol. 15(11), pages 1-25, May.
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    5. Diankai Wang & Inna Gryshova & Anush Balian & Mykola Kyzym & Tetiana Salashenko & Viktoriia Khaustova & Olexandr Davidyuk, 2022. "Assessment of Power System Sustainability and Compromises between the Development Goals," Sustainability, MDPI, vol. 14(4), pages 1-23, February.
    6. Saeidi, Reza & Noorollahi, Younes & Aghaz, Javad & Chang, Soowon, 2023. "FUZZY-TOPSIS method for defining optimal parameters and finding suitable sites for PV power plants," Energy, Elsevier, vol. 282(C).

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