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Resource use and greenhouse gas intensity of Australian beef production: 1981–2010

Author

Listed:
  • Wiedemann, S.G.
  • Henry, B.K.
  • McGahan, E.J.
  • Grant, T.
  • Murphy, C.M.
  • Niethe, G.

Abstract

Over the past three decades major changes have occurred in Australia's beef industry, affecting productivity and potentially the amount of resources used and environmental impacts from production. Using a life cycle assessment (LCA) approach with a ‘cradle-to-farm gate’ boundary the changes in greenhouse gas (GHG) emission intensity and key resource use efficiency factors (water use, fossil fuel energy demand and land occupation) are reported for the 30 years from 1981 to 2010, for the Australian beef industry. The analysis showed that over the three decades since 1981 there has been a decrease in GHG emission intensity (excluding land use change emissions) of 14% from 15.3 to 13.1 kg CO2-e/kg liveweight (LW). The improvement was largely due to efficiency gains through heavier slaughter weights, increases in growth rates in grass-fed cattle, improved survival rates and greater numbers of cattle being finished on grain. However, the increase in supplement and grain use on farms, and the increase in feedlot finishing, resulted in a twofold increase in fossil fuel energy demand for beef production over the same time. Fresh water consumption for beef production dropped to almost a third from 1465 L/kg LW in 1981 to 515 L/kg LW in 2010. Three contributing factors for this dramatic reduction in water use were: (i)an increase in the competitive demand for irrigation water, resulting in a transfer away from pasture for cattle to higher value industries such as horticulture, (ii) an initiative to cap free flowing artesian bores in the rangelands, and (iii) an overall decline in water available for agriculture compared to industrial and domestic uses. While there was higher uncertainty relating to estimates of land occupation and emissions from land use (LU) and direct land use change (dLUC), an inventory of land occupation indicated a decline in non-arable land occupation of about 19%, but a sevenfold increase in land occupation for feed production, albeit from a low base in 1981. GHG emissions associated with LU and dLUC for grazing were estimated to have declined by around 42% since 1981, due largely to legislated restrictions on broad-scale deforestation which were introduced progressively between 1996 and 2006. This paper discusses the prospects and challenges for further gains in resource use efficiency and reductions in greenhouse gas intensity for Australian beef production.

Suggested Citation

  • Wiedemann, S.G. & Henry, B.K. & McGahan, E.J. & Grant, T. & Murphy, C.M. & Niethe, G., 2015. "Resource use and greenhouse gas intensity of Australian beef production: 1981–2010," Agricultural Systems, Elsevier, vol. 133(C), pages 109-118.
    • Handle: RePEc:eee:agisys:v:133:y:2015:i:c:p:109-118
    DOI: 10.1016/j.agsy.2014.11.002
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    References listed on IDEAS

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    1. Bradley G. Ridoutt & Peerasak Sanguansri & Gregory S. Harper, 2011. "Comparing Carbon and Water Footprints for Beef Cattle Production in Southern Australia," Sustainability, MDPI, vol. 3(12), pages 1-13, December.
    2. Vergé, X.P.C. & Dyer, J.A. & Desjardins, R.L. & Worth, D., 2008. "Greenhouse gas emissions from the Canadian beef industry," Agricultural Systems, Elsevier, vol. 98(2), pages 126-134, September.
    3. Pelletier, Nathan & Pirog, Rich & Rasmussen, Rebecca, 2010. "Comparative life cycle environmental impacts of three beef production strategies in the Upper Midwestern United States," Agricultural Systems, Elsevier, vol. 103(6), pages 380-389, July.
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    2. Mayberry, Dianne & Bartlett, Harriet & Moss, Jonathan & Davison, Thomas & Herrero, Mario, 2019. "Pathways to carbon-neutrality for the Australian red meat sector," Agricultural Systems, Elsevier, vol. 175(C), pages 13-21.
    3. Francisco Ascui & Theodor F. Cojoianu, 2019. "Implementing natural capital credit risk assessment in agricultural lending," Business Strategy and the Environment, Wiley Blackwell, vol. 28(6), pages 1234-1249, September.
    4. Ramírez-Restrepo, Carlos A. & Vera-Infanzón, Raul R. & Rao, Idupulapati M., 2020. "Predicting methane emissions, animal-environmental metrics and carbon footprint from Brahman (Bos indicus) breeding herd systems based on long-term research on grazing of neotropical savanna and Brach," Agricultural Systems, Elsevier, vol. 184(C).
    5. Isaac A. Aboagye & Marcos R. C. Cordeiro & Tim A. McAllister & Kim H. Ominski, 2021. "Productivity-Enhancing Technologies. Can Consumer Choices Affect the Environmental Footprint of Beef?," Sustainability, MDPI, vol. 13(8), pages 1-19, April.
    6. Putman, Ben & Thoma, Greg & Burek, Jasmina & Matlock, Marty, 2017. "A retrospective analysis of the United States poultry industry: 1965 compared with 2010," Agricultural Systems, Elsevier, vol. 157(C), pages 107-117.

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    Keywords

    GHG; Carbon; Water; LCA; Energy; Land;
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