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Mitigating energy demand sector emissions: The integrated modelling perspective

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  • Edelenbosch, O.Y.
  • van Vuuren, D.P.
  • Blok, K.
  • Calvin, K.
  • Fujimori, S.

Abstract

Limiting climate change below a given temperature will require fundamental changes in the current energy system, both in the energy supply and the energy demand sectors. Previous global model-based analyses, however, have focused mostly on energy supply transformations. Therefore, in this study we respond to this knowledge gap by analysing the future energy demand projections in both baseline and climate policy scenarios of global models in detail. We examine the projections for the industry, transport and buildings sectors across four models and three different reference scenarios from the Shared-Socioeconomic Pathway framework by applying a decomposition analysis. We compare the projected demand side mitigation efforts to a more detailed, sector-specific, technology-oriented assessment of demand-side abatement potential for the year 2030. Without climate policy, model-based projections show that baseline emissions can grow rapidly in industry and transport sectors, but are also highly uncertain across models. The decomposition analysis shows that the key uncertainty across the global scenarios is the projected final energy per capita. For modellers therefore there lies a challenge to better understand drivers of future energy efficiency and service demand, that contribute to the projected energy demand. This model enhancement would moreover allow to evaluate policy measures that can impact this relation. The technology assessment estimates that in particular in the transport and buildings sector there is a higher potential to reduce demand-side emissions through energy efficiency improvements than implemented in the scenarios. Improved insulation, higher electric vehicle penetration rates and modal shift for example could reduce final energy demand to lower levels in the short term than currently projected, reducing the dependency on fuel switching required in current scenarios to meet the stringent climate targets.

Suggested Citation

  • Edelenbosch, O.Y. & van Vuuren, D.P. & Blok, K. & Calvin, K. & Fujimori, S., 2020. "Mitigating energy demand sector emissions: The integrated modelling perspective," Applied Energy, Elsevier, vol. 261(C).
    • Handle: RePEc:eee:appene:v:261:y:2020:i:c:s0306261919320343
    DOI: 10.1016/j.apenergy.2019.114347
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    1. Masahiro Sugiyama & Osamu Akashi & Kenichi Wada & Amit Kanudia & Jun Li & John Weyant, 2014. "Energy efficiency potentials for global climate change mitigation," Climatic Change, Springer, vol. 123(3), pages 397-411, April.
    2. Pietzcker, Robert C. & Ueckerdt, Falko & Carrara, Samuel & de Boer, Harmen Sytze & Després, Jacques & Fujimori, Shinichiro & Johnson, Nils & Kitous, Alban & Scholz, Yvonne & Sullivan, Patrick & Ludere, 2017. "System integration of wind and solar power in integrated assessment models: A cross-model evaluation of new approaches," Energy Economics, Elsevier, vol. 64(C), pages 583-599.
    3. Brian O’Neill & Elmar Kriegler & Keywan Riahi & Kristie Ebi & Stephane Hallegatte & Timothy Carter & Ritu Mathur & Detlef Vuuren, 2014. "A new scenario framework for climate change research: the concept of shared socioeconomic pathways," Climatic Change, Springer, vol. 122(3), pages 387-400, February.
    4. Felix Creutzig, 2016. "Evolving Narratives of Low-Carbon Futures in Transportation," Transport Reviews, Taylor & Francis Journals, vol. 36(3), pages 341-360, May.
    5. Edelenbosch, O.Y. & Kermeli, K. & Crijns-Graus, W. & Worrell, E. & Bibas, R. & Fais, B. & Fujimori, S. & Kyle, P. & Sano, F. & van Vuuren, D.P., 2017. "Comparing projections of industrial energy demand and greenhouse gas emissions in long-term energy models," Energy, Elsevier, vol. 122(C), pages 701-710.
    6. Global Energy Assessment Writing Team,, 2012. "Global Energy Assessment," Cambridge Books, Cambridge University Press, number 9781107005198.
    7. Allwood, Julian M. & Ashby, Michael F. & Gutowski, Timothy G. & Worrell, Ernst, 2011. "Material efficiency: A white paper," Resources, Conservation & Recycling, Elsevier, vol. 55(3), pages 362-381.
    8. Ang, B. W., 2004. "Decomposition analysis for policymaking in energy:: which is the preferred method?," Energy Policy, Elsevier, vol. 32(9), pages 1131-1139, June.
    9. G. Marangoni & M. Tavoni & V. Bosetti & E. Borgonovo & P. Capros & O. Fricko & D. E. H. J. Gernaat & C. Guivarch & P. Havlik & D. Huppmann & N. Johnson & P. Karkatsoulis & I. Keppo & V. Krey & E. Ó Br, 2017. "Sensitivity of projected long-term CO2 emissions across the Shared Socioeconomic Pathways," Nature Climate Change, Nature, vol. 7(2), pages 113-117, February.
    10. Volker Krey & Gunnar Luderer & Leon Clarke & Elmar Kriegler, 2014. "Getting from here to there – energy technology transformation pathways in the EMF27 scenarios," Climatic Change, Springer, vol. 123(3), pages 369-382, April.
    11. Elmar Kriegler & John Weyant & Geoffrey Blanford & Volker Krey & Leon Clarke & Jae Edmonds & Allen Fawcett & Gunnar Luderer & Keywan Riahi & Richard Richels & Steven Rose & Massimo Tavoni & Detlef Vuu, 2014. "The role of technology for achieving climate policy objectives: overview of the EMF 27 study on global technology and climate policy strategies," Climatic Change, Springer, vol. 123(3), pages 353-367, April.
    12. Global Energy Assessment Writing Team,, 2012. "Global Energy Assessment," Cambridge Books, Cambridge University Press, number 9780521182935.
    13. Fais, Birgit & Sabio, Nagore & Strachan, Neil, 2016. "The critical role of the industrial sector in reaching long-term emission reduction, energy efficiency and renewable targets," Applied Energy, Elsevier, vol. 162(C), pages 699-712.
    14. Volker Krey, 2014. "Global energy-climate scenarios and models: a review," Wiley Interdisciplinary Reviews: Energy and Environment, Wiley Blackwell, vol. 3(4), pages 363-383, July.
    15. van Sluisveld, Mariësse A.E. & Martínez, Sara Herreras & Daioglou, Vassilis & van Vuuren, Detlef P., 2016. "Exploring the implications of lifestyle change in 2°C mitigation scenarios using the IMAGE integrated assessment model," Technological Forecasting and Social Change, Elsevier, vol. 102(C), pages 309-319.
    16. Nejat, Payam & Jomehzadeh, Fatemeh & Taheri, Mohammad Mahdi & Gohari, Mohammad & Abd. Majid, Muhd Zaimi, 2015. "A global review of energy consumption, CO2 emissions and policy in the residential sector (with an overview of the top ten CO2 emitting countries)," Renewable and Sustainable Energy Reviews, Elsevier, vol. 43(C), pages 843-862.
    17. Bale, Catherine S.E. & Varga, Liz & Foxon, Timothy J., 2015. "Energy and complexity: New ways forward," Applied Energy, Elsevier, vol. 138(C), pages 150-159.
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