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Sustainability assessment of catalyst design on CO2-derived fuel production

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  • Shadbahr, Jalil
  • Peeples, Craig A.
  • Pahija, Ergys
  • Panaritis, Christopher
  • Boffito, Daria Camilla
  • Patience, Gregory
  • Bensebaa, Farid

Abstract

Levelized carbon cost abatement (LCCA) and technology learning curves (TLC) are combined to assess the current technology gaps for expediting the deployment of CO2-based renewable fuels. This study is conducted across three levels: Assessing the impact of the Fischer-Tropsch Synthesis (FTS) catalyst improvement on products, estimating the potential reduction in CO2 emissions, and calculating the cost reduction per unit of avoided CO2 emissions. A novel hybrid approach combines bottom-up TEA and LCA tools to assess FTS catalysts, while top-down TLC methodology evaluates future projections of the CO2 to jet fuel (CtJ) platform. The evaluation and comparison of the newly designed FTS catalyst (CYL) and a conventional catalyst (COC) on the CtJ platform are conducted within this scope. Replacing COC with CYL leads to an increase of >170 % in catalyst cost. However, despite the increase in catalyst cost, the overall fuel production of the CtJ platform is boosted by 16 %, and the energy efficiency is improved by +13 %. Consequently, the CYL catalyst enables the production of jet fuel and diesel at a lower cost (−15 % to −17 %) compared to COC from 2027 to 2050. Furthermore, for both cases' equal net CO2 capture, CYL requires 15 % lower CO2 capture and thus 41 % lower CO2 emissions from the CtJ platform than COC. LCCA of CO2-derived fuels is projected to be very close to the $170/tonne CO2 carbon tax target in 2030. Thus, CO2-derived jet fuels are expected to compete with fossil fuels in the Canadian market.

Suggested Citation

  • Shadbahr, Jalil & Peeples, Craig A. & Pahija, Ergys & Panaritis, Christopher & Boffito, Daria Camilla & Patience, Gregory & Bensebaa, Farid, 2025. "Sustainability assessment of catalyst design on CO2-derived fuel production," Renewable and Sustainable Energy Reviews, Elsevier, vol. 208(C).
    • Handle: RePEc:eee:rensus:v:208:y:2025:i:c:s1364032124007378
    DOI: 10.1016/j.rser.2024.115011
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    References listed on IDEAS

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