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Carbon footprint of renewable diesel from palm oil, jatropha oil and rapeseed oil

Author

Listed:
  • Uusitalo, V.
  • Väisänen, S.
  • Havukainen, J.
  • Havukainen, M.
  • Soukka, R.
  • Luoranen, M.

Abstract

This paper examines the carbon footprint of renewable diesel (RD) production from palm oil, jatropha oil and rapeseed oil. Greenhouse gas (GHG) emissions from land use change (LUC), feedstock cultivation processes, and RD production and delivery are studied from a life-cycle assessment perspective. The goal of the paper is to calculate the carbon footprint of RD and recommend ways of decreasing it. Our findings indicate that the key contributors to the carbon footprint of RD are found in the GHG emissions of LUC, feedstock cultivation and oil extraction processes. In the case of palm oil, methane collection from palm oil mill effluent (POME) is one of the main contributors to the carbon footprint. Our calculations demonstrate that the RD production and distribution stages generate relatively low GHG emissions compared to the other life-cycle stages; therefore, attention should be focused on the contributing role of LUC and cultivation processes to the RD carbon footprint. If cultivation requires a land use conversion from forest to cultivated land, the resultant GHG emissions exceed emission levels from fossil fuels. If feedstock cultivation is done with no LUC or if grasslands are the feedstock cultivation site, then cultivation GHG emission reductions are achieved. In some cases, RD production may even act as a sink for GHGs. Due to its quality RD can be used without blend-wall limitations in vehicles; therefore, it offers a higher biofuel potential for the diesel sector than does traditional biodiesel. The article concludes by discussing the implications of the findings for RD in light of GHG emission reductions.

Suggested Citation

  • Uusitalo, V. & Väisänen, S. & Havukainen, J. & Havukainen, M. & Soukka, R. & Luoranen, M., 2014. "Carbon footprint of renewable diesel from palm oil, jatropha oil and rapeseed oil," Renewable Energy, Elsevier, vol. 69(C), pages 103-113.
    • Handle: RePEc:eee:renene:v:69:y:2014:i:c:p:103-113
    DOI: 10.1016/j.renene.2014.03.020
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    References listed on IDEAS

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    4. Väisänen, S. & Havukainen, J. & Uusitalo, V. & Havukainen, M. & Soukka, R. & Luoranen, M., 2016. "Carbon footprint of biobutanol by ABE fermentation from corn and sugarcane," Renewable Energy, Elsevier, vol. 89(C), pages 401-410.
    5. Culman, María & de Farias, Claudio M. & Bayona, Cristihian & Cabrera Cruz, José Daniel, 2019. "Using agrometeorological data to assist irrigation management in oil palm crops: A decision support method and results from crop model simulation," Agricultural Water Management, Elsevier, vol. 213(C), pages 1047-1062.
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    8. Archer, Sophie A. & Murphy, Richard J. & Steinberger-Wilckens, Robert, 2018. "Methodological analysis of palm oil biodiesel life cycle studies," Renewable and Sustainable Energy Reviews, Elsevier, vol. 94(C), pages 694-704.
    9. Azhar, Badrul & Nobilly, Frisco & Lechner, Alex M. & Tohiran, Kamil Azmi & Maxwell, Thomas M.R. & Zulkifli, Raja & Kamel, Mohd Fathil & Oon, Aslinda, 2021. "Mitigating the risks of indirect land use change (ILUC) related deforestation from industrial palm oil expansion by sharing land access with displaced crop and cattle farmers," Land Use Policy, Elsevier, vol. 107(C).
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