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Including bottom-up emission abatement technologies in a large-scale global model for policy assessments

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  • Weitzel, Matthias
  • Saveyn, Bert
  • Vandyck, Toon

Abstract

Economic models with global and economy-wide coverage can be useful tools to assess the impact of energy and environmental policies, but often disregard finer technological details of emission abatement measures. We present a framework for integrating and preserving detailed bottom-up information for end-of-pipe abatement technologies into a large-scale numerical model. Using an activity analysis approach, we capture non-linearities that typically characterise bottom-up abatement cost curves derived from discrete technology options. The model framework is flexible and can accommodate greenhouse gas and air pollution abatement, as well as modelling carbon capture and storage (CCS). Here, we illustrate this approach for non-CO2 greenhouse gases in a large-scale Computable General Equilibrium (CGE) model and compare results with a fitted marginal abatement curve and with completely excluding non-CO2 greenhouse gases. Results show that excluding non-CO2 abatement options leads to an overestimation of the total abatement cost. When the detailed bottom-up technology implementation is replaced by an estimated smooth marginal abatement cost curve, significant over- or underestimations of abatement levels and costs can emerge for particular pollutant-sector-region combinations.

Suggested Citation

  • Weitzel, Matthias & Saveyn, Bert & Vandyck, Toon, 2019. "Including bottom-up emission abatement technologies in a large-scale global model for policy assessments," Conference papers 333034, Purdue University, Center for Global Trade Analysis, Global Trade Analysis Project.
  • Handle: RePEc:ags:pugtwp:333034
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    File URL: https://ageconsearch.umn.edu/record/333034/files/9193.pdf
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    1. Kimon Keramidas & Alban Kitous & Jacques Despres & Andreas Schmitz & Ana Diaz Vazquez & Silvana Mima & Peter Russ & Tobias Wiesenthal, 2017. "POLES-JRC model documentation," JRC Research Reports JRC107387, Joint Research Centre.
    2. Detlef P. van Vuuren & Elke Stehfest & David E. H. J. Gernaat & Maarten Berg & David L. Bijl & Harmen Sytze Boer & Vassilis Daioglou & Jonathan C. Doelman & Oreane Y. Edelenbosch & Mathijs Harmsen & A, 2018. "Alternative pathways to the 1.5 °C target reduce the need for negative emission technologies," Nature Climate Change, Nature, vol. 8(5), pages 391-397, May.
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    1. Norman-Lopez, Ana & Wojtowicz, Krzysztof & Garaffa, Rafael & Tamba, Marie, 2022. "Disaggregating air, land and maritime transport sectors in the GTAP database," Conference papers 333415, Purdue University, Center for Global Trade Analysis, Global Trade Analysis Project.
    2. Janos Varga & Werner Roeger & Jan in ’t Veld, 2021. "E-QUEST – A Multi-Region Sectoral Dynamic General Equilibrium Model with Energy Model Description and Applications to Reach the EU Climate Targets," European Economy - Discussion Papers 146, Directorate General Economic and Financial Affairs (DG ECFIN), European Commission.
    3. Vandyck, Toon & Weitzel, Matthias & Wojtowicz, Krzysztof & Rey Los Santos, Luis & Maftei, Anamaria & Riscado, Sara, 2021. "Climate policy design, competitiveness and income distribution: A macro-micro assessment for 11 EU countries," Energy Economics, Elsevier, vol. 103(C).
    4. Varga, Janos & Roeger, Werner & in ’t Veld, Jan, 2022. "E-QUEST: A multisector dynamic general equilibrium model with energy and a model-based assessment to reach the EU climate targets," Economic Modelling, Elsevier, vol. 114(C).
    5. KERAMIDAS Kimon & FOSSE Florian & DIAZ VAZQUEZ Ana & DOWLING Paul & GARAFFA Rafael & DESPRÉS Jacques & RUSS Hans Peter & SCHADE Burkhard & SCHMITZ Andreas & SORIA RAMIREZ Antonio & VANDYCK Toon & WEIT, 2021. "Global Energy and Climate Outlook 2021: Advancing towards climate neutrality," JRC Research Reports JRC126767, Joint Research Centre.

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