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Energy and climate benefits of bioelectricity from low-input short rotation woody crops on agricultural land over a two-year rotation

Author

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  • Njakou Djomo, S.
  • El Kasmioui, O.
  • De Groote, T.
  • Broeckx, L.S.
  • Verlinden, M.S.
  • Berhongaray, G.
  • Fichot, R.
  • Zona, D.
  • Dillen, S.Y.
  • King, J.S.
  • Janssens, I.A.
  • Ceulemans, R.

Abstract

Short-rotation woody crops (SRWCs) are a promising means to enhance the EU renewable energy sources while mitigating greenhouse gas (GHG) emissions. However, there are concerns that the GHG mitigation potential of bioelectricity may be nullified due to GHG emissions from direct land use changes (dLUCs). In order to evaluate quantitatively the GHG mitigation potential of bioelectricity from SRWC we managed an operational SRWC plantation (18.4ha) for bioelectricity production on a former agricultural land without supplemental irrigation or fertilization. We traced back to the primary energy level all farm labor, materials, and fossil fuel inputs to the bioelectricity production. We also sampled soil carbon and monitored fluxes of GHGs between the SRWC plantation and the atmosphere. We found that bioelectricity from SRWCs was energy efficient and yielded 200–227% more energy than required to produce it over a two-year rotation. The associated land requirement was 0.9m2kWhe-1 for the gasification and 1.1m2kWhe-1 for the combustion technology. Converting agricultural land into the SRWC plantation released 2.8 ± 0.2tCO2eha−1, which represented ∼89% of the total GHG emissions (256–272gCO2ekWhe-1) of bioelectricity production. Despite its high share of the total GHG emissions, dLUC did not negate the GHG benefits of bioelectricity. Indeed, the GHG savings of bioelectricity relative to the EU non-renewable grid mix power ranged between 52% and 54%. SRWC on agricultural lands with low soil organic carbon stocks are encouraging prospects for sustainable production of renewable energy with significant climate benefits.

Suggested Citation

  • Njakou Djomo, S. & El Kasmioui, O. & De Groote, T. & Broeckx, L.S. & Verlinden, M.S. & Berhongaray, G. & Fichot, R. & Zona, D. & Dillen, S.Y. & King, J.S. & Janssens, I.A. & Ceulemans, R., 2013. "Energy and climate benefits of bioelectricity from low-input short rotation woody crops on agricultural land over a two-year rotation," Applied Energy, Elsevier, vol. 111(C), pages 862-870.
    • Handle: RePEc:eee:appene:v:111:y:2013:i:c:p:862-870
    DOI: 10.1016/j.apenergy.2013.05.017
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    5. Rugani, Benedetto & Golkowska, Katarzyna & Vázquez-Rowe, Ian & Koster, Daniel & Benetto, Enrico & Verdonckt, Pieter, 2015. "Simulation of environmental impact scores within the life cycle of mixed wood chips from alternative short rotation coppice systems in Flanders (Belgium)," Applied Energy, Elsevier, vol. 156(C), pages 449-464.
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    9. Wang, Zhan & Deng, Xiangzheng & Bai, Yuping & Chen, Jiancheng & Zheng, Wentang, 2016. "Land use structure and emission intensity at regional scale: A case study at the middle reach of the Heihe River basin," Applied Energy, Elsevier, vol. 183(C), pages 1581-1593.
    10. Vanbeveren, Stefan P.P. & Spinelli, Raffaele & Eisenbies, Mark & Schweier, Janine & Mola-Yudego, Blas & Magagnotti, Natascia & Acuna, Mauricio & Dimitriou, Ioannis & Ceulemans, Reinhart, 2017. "Mechanised harvesting of short-rotation coppices," Renewable and Sustainable Energy Reviews, Elsevier, vol. 76(C), pages 90-104.
    11. Njakou Djomo, S. & Witters, N. & Van Dael, M. & Gabrielle, B. & Ceulemans, R., 2015. "Impact of feedstock, land use change, and soil organic carbon on energy and greenhouse gas performance of biomass cogeneration technologies," Applied Energy, Elsevier, vol. 154(C), pages 122-130.
    12. Yang, Jin & Chen, Bin, 2014. "Global warming impact assessment of a crop residue gasification project—A dynamic LCA perspective," Applied Energy, Elsevier, vol. 122(C), pages 269-279.

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