Aligning the Energy Transition with the Sustainable Development Goals

This open access book brings together concrete analyses from around the world, spanning various scales, that shed light on strategies for implementing essential energy and climate transitions within the broader context of UN Sustainable Development Goal (SDG) imperatives.

Specifically, the book exemplifies the advancement, adaptation, and utilization of energy systems models to address intricate policy issues around pathways to achieve net-zero emissions, enhance energy security, optimize investments, and understand their societal implications. It explores the intricate connections between the SDGs concerning energy, climate action, and other developmental priorities such as employment and economic growth, industrial innovation, urban development, responsible consumption and production, and collaborative partnerships.

Organized into four sections, the book illustrates the necessary adjustments of energy system models to guide SDGs, evaluates the role of modeling to advance both renewable energy and energy security, and showcases how energy systems are harnessed to engage with international, national, and local policymakers.

This book is available open access under a Creative Commons Attribution 4.0 International License via link.springer.com.

This book is open access, which means that you have free and unlimited access Shows how energy systems models are being improved and utilised to address complex policy questions Covers zero emission pathways, energy security, industrial development, optimal investments, their societal consequences This book is open access, which means that you have free and unlimited access

Auteur

Maryse Labriet is director of Eneris Environment Energy Consultants, based in Spain, and faculty lecturer at the EOI-Business School in Madrid. Defining and assessing policies, projects and investments, advancing knowledge and building capacities form the basis of her intervention approach to meet the climate and energy access imperatives. As a consultant, she provides strategic support to international and national, governmental and non-governmental entities in Europe, Africa, Central and South America. As a researcher, she codeveloped and applied the global TIMES Integrated Assessment Model (TIAM-WORLD) to explore climate agreements and energy transition pathways. The model is now used by more than 10 institutions all around the world and by the IEA's Technology Collaboration Programme on energy systems modelling (IEA-ETSAP). She is an Industrial Engineer (France) and holds a PhD in Environmental Sciences (Canada).

Kari Espegren is a principal scientist in energy systems analysis at the research foundation IFE in Norway. She holds degree in Mechanical Engineering from the Norwegian University of Science and Technology from 1986. Her research focus is on using energy systems models in interaction with other sector specific models, such as economy model or power models, to understand and inform policy makers and industrial actors through analysis of transition pathways. She is the Research Area manager for Transition pathways studies in the Norwegian Centre for Energy Transition Strategies. Espegren is an experienced research project coordinator, and her main project contribution is related to how hydrogen can be integrated in a sustainable manner. She has represented Norway in the Executive committee the IEA's Technology Collaboration Programme on energy systems modelling (IEA-ETSAP) since 2008, and she was the Operating Agent of the IEA-ETSAP from 2020 to 2023.

George Giannakidis holds a Mechanical Engineering Degree (1989) from the Aristotle University of Thessaloniki and a PhD in Computational Fluid Dynamics (1993) from Imperial College, University of London. He was a senior consultant and the head of the Laboratory for Energy Systems Analysis in the Centre for Renewable Energy Sources and Saving in Greece for twenty years. He is currently Co-founder and Managing Director of MRC Greece. His scientific interests include energy systems analysis, energy economics and energy policy. He is in particular interested in the evaluation of the necessary energy policies for large scale penetration of renewable energies. He has participated as a project partner and coordinator in a number of EU funded projects on energy planning and renewable energy sources penetration into the energy system. He has also participated in the formulation of the Greek National Action Plans for energy efficiency, cogeneration of heat and power, and renewable energy sources. From January 2013 to December 2016 he represented CRES as the Operating Agent of the IEA's Technology Collaboration Programme on energy systems modelling (IEA-ETSAP) and since January 2017 he is the Project Head of IEA-ETSAP.

Brian Ó Gallachóir is Associate Vice-President of Sustainability at University College Cork (UCC), delivering on UCC's ambitious plans to consolidate its role as a leading university of sustainability. Brian established energy systems modelling capacity in Ireland over the past 20 years and is a recognised international leader in this field, including as elected Chair of IEA ETSAP Executive Committee. His research has underpinned Irish and EU energy and climate mitigation policies and energy company strategies. Brian has also increased the transdisciplinary nature of climate mitigation research and this is particularly evident in the multi-stakeholder Dingle Peninsula 2030 partnership project. He received the Science Foundation Ireland Best International Engagement Award 2020 and Best Engaged Research Award

Contenu

Foreword.- Preface.- Introduction.- PART I - ADAPTING.- ENERGY SYSTEM MODELS TO INFORM SDGs.- 1. Implications of the NetZero Transition Across Spectrum of SDG Indicators: Linking Global Energy System and CGE Models.- 2. Accelerating the Performance of Large-Scale TIMES Models in the Modelling of SDGs.- 3. On the Fairness and Feasibility of Implementing Low-Energy Demand Scenarios to Achieve Net Zero.- 4. A Global and Regional Energy System Analysis of Carbon Dioxide Removal as Climate Sustainable Action considering Land and Water Challenges.- 5. Structure Applications, and Future Perspective of the TEMOA-Italy Model.- PART II INCREASING RENEWABLE ENERGY USING ENERGY SYSTEM MODELS.- 6. Assessing the Impact of Climate Variability on Wind Energy Potential in Decarbonization Scenarios in Energy Systems Models.- 7. Clean and Affordable Norwegian Offshore Wind to Facilitate the European Low-Carbon Transition.- 8. The Nordics as Green Fuel and Power Hub?.- 9. Modelling Circular Economy in the Spanish Pulp and Paper Industry in TIMES. - 10. Estimating the Cost of Decarbonising an Economy.- PART III INFORMING ENERGY SECURITY WITH ENERGY SYSTEM MODELS.- 11. Modelling of Demands of Selected Minerals and Metals in Clean Energy Transition with 1.52.0 °C Mitigation Targets.- 12. Security of Supply Emission Free Energy Carriers and the Impact of Trade to Achieve the 1.5 °C Target.- 13. The Gas Crise and the Impact on the Pathway to a Climate Neutral Energy System till 2045.- 14. Net Zero Transition in Ukraine: Implications for Sustainable Development Goals and Energy Security.- 15. From Dependency to Diversification: How SDG7 Can Help Algeria Overcome Dutch Disease.- PART IV ENGAGING WITH POLICY-MAKERS ON ENERGY SYSTEM MODELS.- 16. Analysis of Low Carbon Transition Pathways by Using an Interdisciplinary Approach.- 17.Crossing Points Between Sustainable Municipalities and Sustainable Energy Systems.- 18. Application of the TIMES model in the World Bank's Country Climate and Development Reports in Europe and Central Asia.- 19. Translating TIMES Scenario Results into Policy Insights to Underpin Climate Action in Ireland.- 20. Retrospective of French Prospective Exercises: Chronicle of A Failure.