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The carbon footprint of lamb: Sources of variation and opportunities for mitigation

Author

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  • Jones, A.K.
  • Jones, D.L.
  • Cross, P.

Abstract

Carbon footprinting can be used to characterise the greenhouse gas emissions profile of agricultural products, providing a baseline against which mitigation targets can be set and progress measured. Farm-level emissions vary in relation to local conditions and management choices. Carbon footprinting models can be used to assess the impact of farm characteristics on emissions; however, the benefits of such models have been underexploited thus far for sheep production. This study estimated the cradle to farm-gate carbon footprints of 64 sheep farms across England and Wales using empirical farm data. This large dataset enabled an assessment of the relationship between farm variables and carbon footprint at a multi-farm level. Mean carbon footprints of 10.85, 12.85 and 17.86kg CO2e/kg live weight finished lamb were recorded for lowland, upland and hill farms respectively, from samples with coefficients of variation of 33%, 23% and 34%. Multiple linear regression models indicated that four farm management variables had a significant impact on the size of the carbon footprint of finished lamb. Irrespective of farm category, these were the number of lambs reared per ewe (head/ewe), lamb growth rate (g/day), the percentage of ewe and replacement ewe lamb flock not mated (%), and concentrate use (kg/livestock unit). Dominance analysis indicated that, of these, the number of lambs reared per ewe mated and lamb growth rate were the most influential. Productivity improvements are arguably most problematic for extensive hill farms; however, the top performing hill farms in this study outperformed the mean lowland and upland farms. The results suggest that, at a national level, the emphasis for reducing the carbon footprint of lamb should be on closing the productivity gap between poor and top performing farms.

Suggested Citation

  • Jones, A.K. & Jones, D.L. & Cross, P., 2014. "The carbon footprint of lamb: Sources of variation and opportunities for mitigation," Agricultural Systems, Elsevier, vol. 123(C), pages 97-107.
  • Handle: RePEc:eee:agisys:v:123:y:2014:i:c:p:97-107
    DOI: 10.1016/j.agsy.2013.09.006
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    References listed on IDEAS

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    4. Morgan-Davies, C. & Kyle, J. & Boman, I.A. & Wishart, H. & McLaren, A. & Fair, S. & Creighton, P., 2021. "A comparison of farm labour, profitability, and carbon footprint of different management strategies in Northern European grassland sheep systems," Agricultural Systems, Elsevier, vol. 191(C).
    5. Pablo L. Peri & Yamina M. Rosas & Brenton Ladd & Ricardo Díaz-Delgado & Guillermo Martínez Pastur, 2020. "Carbon Footprint of Lamb and Wool Production at Farm Gate and the Regional Scale in Southern Patagonia," Sustainability, MDPI, vol. 12(8), pages 1-26, April.
    6. Alexandru Marius Deac & Adriana Sebastiana Musca & Stefania Dana Mesesan & Marius Gavril Aipatioaie & Adrian Ionascu & Viorica Cosier & Attila Cristian Ratiu & Ileana Miclea & Ioan Ladosi & Marius Zah, 2023. "Single-Nucleotide Polymorphisms Identified within Exon 2 of Fertility-Associated Bone Morphogenetic Protein (BMP15) Gene in Three Romanian Sheep Breeds," Agriculture, MDPI, vol. 13(5), pages 1-14, April.
    7. Toro-Mujica, Paula & Aguilar, Claudio & Vera, Raúl R. & Bas, Fernando, 2017. "Carbon footprint of sheep production systems in semi-arid zone of Chile: A simulation-based approach of productive scenarios and precipitation patterns," Agricultural Systems, Elsevier, vol. 157(C), pages 22-38.
    8. Recktenwald, Erin B. & Ehrhardt, Richard A., 2024. "Greenhouse gas emissions from a diversity of sheep production systems in the United States," Agricultural Systems, Elsevier, vol. 217(C).
    9. Farrell, L. & Herron, J. & Pabiou, T. & McHugh, N. & McDermott, K. & Shalloo, L. & O'Brien, D. & Bohan, A., 2022. "Modelling the production, profit, and greenhouse gas emissions of Irish sheep flocks divergent in genetic merit," Agricultural Systems, Elsevier, vol. 201(C).

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