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Site-specific calculation of corn bioethanol carbon footprint with Life Cycle Assessment

Author

Listed:
  • Ponieman, Karen D.
  • Bongiovanni, Rodolfo
  • Battaglia, Martin L.
  • Hilbert, Jorge A.
  • Cipriotti, Pablo A.
  • Espósito, Gabriel

Abstract

The agricultural stage is a hotspot in the carbon footprint (CF) of the production of corn bioethanol and, within this stage, the production and use of nitrogen fertilisers is the subprocess that has the greatest incidence. The current research project aims to incorporate the environmental impacts in the analysis of optimum nitrogen fertiliser rates, in addition to the agricultural and economic outputs that have been widely used in previous studies. We seek to obtain functions that describe the CF at different nitrogen rates, topographic positions and climatic conditions, incorporating them as objective functions in multiobjective optimization procedures. In order to achieve this aim, the first step is to quantify the corn bioethanol CF with Life Cycle Assessment (LCA) methodology, for fertilisation and yield data at a site-specific scale. On-farm research trials were conducted in 18 corn fields where agricultural producers applied up to 6 levels of strip nitrogen fertilisation, through an elevation gradient, in 5 crop seasons distributed over 12 years, in the centre-south region of Córdoba province, Argentina. The corn transportation and its industrial process were considered as fixed subsystems for this research. The LCA methodology follows the ISO 14067:2018 standard and the Intergovernmental Panel on Climate Change (IPCC) guidelines (2019). The R software was used to process the large datasets. A bioethanol corn CF map at a site-specific scale was achieved. As opposed to a single CF value per field, assessing the CF at a site-specific scale allows us to explore the within-field variability caused by different input rates, its interaction with environmental factors and crop yields. Spatial and temporal statistical analysis is needed to understand the relation between nitrogen fertilisation and corn bioethanol CF. Furthermore, we expect to consider the function that best represents this relation in the definition of optimum site-specific nitrogen rate.

Suggested Citation

  • Ponieman, Karen D. & Bongiovanni, Rodolfo & Battaglia, Martin L. & Hilbert, Jorge A. & Cipriotti, Pablo A. & Espósito, Gabriel, 2023. "Site-specific calculation of corn bioethanol carbon footprint with Life Cycle Assessment," Agri-Tech Economics Papers 344397, Harper Adams University, Land, Farm & Agribusiness Management Department.
    • Handle: RePEc:ags:haaepa:344397
    DOI: 10.22004/ag.econ.344397
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    as
    1. Unescap-Sswa, 2015. "Enhancing the sustainability of development," SSWA Policy Briefs 0005, United Nations Economic and Social Commission for Asia and the Pacific (ESCAP) South and South-West Asia Office.
    2. Muschietti-Piana, Maria del Pilar & Cipriotti, Pablo Ariel & Urricariet, Susana & Peralta, Nahuel Raul & Niborski, Mauricio, 2018. "Using site-specific nitrogen management in rainfed corn to reduce the risk of nitrate leaching," Agricultural Water Management, Elsevier, vol. 199(C), pages 61-70.
    3. Rajagopal, 2015. "Sustainable Marketing," Palgrave Macmillan Books, in: The Butterfly Effect in Competitive Markets, chapter 8, pages 194-219, Palgrave Macmillan.
    4. Robert Finger & Scott M. Swinton & Nadja El Benni & Achim Walter, 2019. "Precision Farming at the Nexus of Agricultural Production and the Environment," Annual Review of Resource Economics, Annual Reviews, vol. 11(1), pages 313-335, October.
    5. Unknown, 2015. "Towards A Sustainable Soil Fertility Strategy in Ghana," Miscellaneous Publications 212898, Michigan State University, Department of Agricultural, Food, and Resource Economics.
    6. Kenneth G. Cassman & Patricio Grassini, 2020. "A global perspective on sustainable intensification research," Nature Sustainability, Nature, vol. 3(4), pages 262-268, April.
    7. Neil R. Miller, 2006. "Is Site-Specific Yield Response Consistent over Time? Does It Pay?," American Journal of Agricultural Economics, Agricultural and Applied Economics Association, vol. 88(2), pages 471-483.
    8. Paul T. M. Ingenbleek & Gé B. C. Backus, 2015. "Organizing Open Innovation for Sustainability," Springer Books, in: Alexander Brem & Éric Viardot (ed.), Adoption of Innovation, edition 127, pages 109-131, Springer.
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    Keywords

    Climate Change; Crop Production/Industries; Farm Management; Sustainability;
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