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RESEARCH FRONT

Influence of climate variability and stocking strategies on greenhouse gas emissions (GHGE), production and profit of a northern Queensland beef cattle herd

Brendan R. Cullen A D , Neil D. MacLeod B , Joe C. Scanlan C and Natalie Doran-Browne A
+ Author Affiliations
- Author Affiliations

A Faculty of Veterinary and Agricultural Sciences, The University of Melbourne, Parkville, Vic. 3010, Australia.

B CSIRO Agriculture Flagship, St Lucia, Qld 4067, Australia.

C Queensland Department of Agriculture and Fisheries, Toowoomba, Qld 4350, Australia.

D Corresponding author. Email: bcullen@unimelb.edu.au

Animal Production Science 58(6) 990-997 https://doi.org/10.1071/AN15608
Submitted: 15 September 2015  Accepted: 16 April 2016   Published: 8 June 2016

Abstract

Previous studies of greenhouse gas emissions (GHGE) from beef production systems in northern Australia have been based on models of ‘steady-state’ herd structures that do not take into account the considerable inter-annual variation in liveweight gain, reproduction and mortality rates that occurs due to seasonal conditions. Nor do they consider the implications of flexible stocking strategies designed to adapt these production systems to the highly variable climate. The aim of the present study was to quantify the variation in total GHGE (t CO2e) and GHGE intensity (t CO2e/t liveweight sold) for the beef industry in northern Australia when variability in these factors was considered. A combined GRASP–Enterprise modelling platform was used to simulate a breeding–finishing beef cattle property in the Burdekin River region of northern Queensland, using historical climate data from 1982–2011. GHGE was calculated using the method of Australian National Greenhouse Gas Inventory. Five different stocking-rate strategies were simulated with fixed stocking strategies at moderate and high rates, and three flexible stocking strategies where the stocking rate was adjusted annually by up to 5%, 10% or 20%, according to pasture available at the end of the growing season. Variation in total annual GHGE was lowest in the ‘fixed moderate’ (~9.5 ha/adult equivalent (AE)) stocking strategy, ranging from 3799 to 4471 t CO2e, and highest in the ‘fixed high’ strategy (~5.9 ha/AE), which ranged from 3771 to 7636 t CO2e. The ‘fixed moderate’ strategy had the least variation in GHGE intensity (15.7–19.4 t CO2e/t liveweight sold), while the ‘flexible 20’ strategy (up to 20% annual change in AE) had the largest range (10.5–40.8 t CO2e/t liveweight sold). Across the five stocking strategies, the ‘fixed moderate’ stocking-rate strategy had the highest simulated perennial grass percentage and pasture growth, highest average rate of liveweight gain (121 kg/steer), highest average branding percentage (74%) and lowest average breeding-cow mortality rate (3.9%), resulting in the lowest average GHGE intensity (16.9 t CO2e/t liveweight sold). The ‘fixed high’ stocking rate strategy (~5.9 ha/AE) performed the poorest in each of these measures, while the three flexible stocking strategies were intermediate. The ‘fixed moderate’ stocking strategy also yielded the highest average gross margin per AE carried and per hectare. These results highlight the importance of considering the influence of climate variability on stocking-rate management strategies and herd performance when estimating GHGE. The results also support a body of previous work that has recommended the adoption of moderate stocking strategies to enhance the profitability and ecological stability of beef production systems in northern Australia.

Additional keywords: reproduction; mortality rate; mitigation.


References

Ash A, McIntosh P, Cullen B, Carberry P, Stafford Smith MS (2007) Constraints and opportunities in applying seasonal climate forecasts in agriculture. Australian Journal of Agricultural Research 58, 952–965.
Constraints and opportunities in applying seasonal climate forecasts in agriculture.Crossref | GoogleScholarGoogle Scholar |

Bentley D, Hegarty RS, Alford AR (2008) Managing livestock enterprises in Australia’s extensive rangelands for greenhouse gas and environmental outcomes: a pastoral company perspective. Australian Journal of Experimental Agriculture 48, 60–64.
Managing livestock enterprises in Australia’s extensive rangelands for greenhouse gas and environmental outcomes: a pastoral company perspective.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD1cXovVGq&md5=d50a5ce0d187b87ce96f31dffde00e23CAS |

Bortolussi G, McIvor JG, Hodgkinson JJ, Coffey SG, Holmes CR (2005a) The northern Australian beef industry, a snapshot. 1. Regional enterprise activity and structure. Australian Journal of Experimental Agriculture 45, 1057–1073.
The northern Australian beef industry, a snapshot. 1. Regional enterprise activity and structure.Crossref | GoogleScholarGoogle Scholar |

Bortolussi G, McIvor JG, Hodgkinson JJ, Coffey SG, Holmes CR (2005b) The northern Australian beef industry, a snapshot. 5. Land and pasture development practices. Australian Journal of Experimental Agriculture 45, 1121–1129.
The northern Australian beef industry, a snapshot. 5. Land and pasture development practices.Crossref | GoogleScholarGoogle Scholar |

Bortolussi G, McIvor JG, Hodgkinson JJ, Coffey SG, Holmes CR (2005c) The northern Australian beef industry, a snapshot. 2. Breeding herd performance and management. Australian Journal of Experimental Agriculture 45, 1075–1091.
The northern Australian beef industry, a snapshot. 2. Breeding herd performance and management.Crossref | GoogleScholarGoogle Scholar |

Bray S, Doran-Browne N, O’Reagain P (2014) Northern Australian pasture and beef systems. 1. Calculation of greenhouse gas emissions. Animal Production Science 54, 1988–1994.

Browne NA, Eckard RJ, Behrendt R, Kingwell RS (2011) A comparative analysis of on-farm greenhouse gas emissions from agricultural enterprises in south eastern Australia. Animal Feed Science and Technology 166–167, 641–652.
A comparative analysis of on-farm greenhouse gas emissions from agricultural enterprises in south eastern Australia.Crossref | GoogleScholarGoogle Scholar |

Browne N, Kingwell R, Behrendt R, Eckard R (2013) The relative profitability of dairy, sheep, beef and grain farm enterprises in southeast Australia under selected rainfall and price scenarios. Agricultural Systems 117, 35–44.
The relative profitability of dairy, sheep, beef and grain farm enterprises in southeast Australia under selected rainfall and price scenarios.Crossref | GoogleScholarGoogle Scholar |

Cullen BR, Eckard RJ, Timms M, Phelps D (2016) The effect of earlier mating and improving fertility on emissions intensity of beef production in a northern Australian herd. The Rangeland Journal

DIRD (2015) ‘Strategic directions for the northern Australia beef industry.’ Available at http://regional.gov.au/regional/ona/nabis.aspx [Verified 21 August 2015]

Fordyce G, Holroyd RG, Taylor J, Kirkland PD (2013) Neospora caninum and reproductive wastage in extensively managed Queensland beef herds. Australian Veterinary Journal 91, 385–390.
Neospora caninum and reproductive wastage in extensively managed Queensland beef herds.Crossref | GoogleScholarGoogle Scholar | 1:STN:280:DC%2BC3sbivFGisw%3D%3D&md5=0e965a6575c680d492a9fa716ca99cfdCAS | 23980832PubMed |

Hall WB, McKeon GM, Carter JO, Day KA, Howden SM, Scanlan JC, Johnston PW, Burrows WH (1998) Climate change in Queensland’s grazing lands: II. An assessment of the impact on animal production from native pastures. The Rangeland Journal 20, 177–205.
Climate change in Queensland’s grazing lands: II. An assessment of the impact on animal production from native pastures.Crossref | GoogleScholarGoogle Scholar |

Harrison MT, Cullen BR, Tomkins NW, McSweeney C, Cohn P, Eckard RJ (2016) The concordance between greenhouse gas emissions, livestock production and profitability of extensive beef farming systems. Animal Production Science 56, 370–384.
The concordance between greenhouse gas emissions, livestock production and profitability of extensive beef farming systems.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC28Xis1amt7c%3D&md5=8280383b7b64dcd4095122f13c4782e8CAS |

Hunt LP (2008) Safe pasture utilisation rates as a grazing managment tool in extensively grazed tropical savannas of northern Australia. The Rangeland Journal 30, 305–315.
Safe pasture utilisation rates as a grazing managment tool in extensively grazed tropical savannas of northern Australia.Crossref | GoogleScholarGoogle Scholar |

Hunt LP, McIvor JG, Grice AC, Bray SG (2014) Principles and guidelines for managing cattle grazing in the grazing lands of northern Australia: stocking rates, pasture resting, prescribed fire, paddock size and water points – a review. The Rangeland Journal 36, 105–119.
Principles and guidelines for managing cattle grazing in the grazing lands of northern Australia: stocking rates, pasture resting, prescribed fire, paddock size and water points – a review.Crossref | GoogleScholarGoogle Scholar |

Johnston PW, McKeon GM, Day KA (1996) Objective ‘safe’ grazing capacities for south-west Queensland Australia: development of a model for individual properties. The Rangeland Journal 18, 244–258.
Objective ‘safe’ grazing capacities for south-west Queensland Australia: development of a model for individual properties.Crossref | GoogleScholarGoogle Scholar |

Jones R (1997) Steer gains, pasture yield and pasture composition on native pasture and native pasture oversown with Indian couch (Bothriochloa pertusa) at three stocking rates. Australian Journal of Experimental Agriculture 37, 755–765.
Steer gains, pasture yield and pasture composition on native pasture and native pasture oversown with Indian couch (Bothriochloa pertusa) at three stocking rates.Crossref | GoogleScholarGoogle Scholar |

MacLeod ND, Ash AJ (2001) Development of a spreadsheet herd dynamics model to assess the economic value of forecasts in extensive grazing enterprises. Oceans to Farms project report no.6, CSIRO Sustainable Ecosystems, Brisbane and Townsville, Qld.

MacLeod ND, Ash AJ, McIvor JG (2004) An economic assessment of the impact of grazing land condition on livestock performance in tropical woodlands. The Rangeland Journal 26, 49–71.
An economic assessment of the impact of grazing land condition on livestock performance in tropical woodlands.Crossref | GoogleScholarGoogle Scholar |

McIvor J (2012) ‘Sustainable management of the Burdekin grazing lands. A technical guide of options for stocking rate management, pasture spelling, infrastructure development and prescribed burning to optimise animal production, profitability, land condition and water quality outcomes.’ (Department of Agriculture, Fisheries and Forestry: Brisbane)

McKeon GM, Hall WB, Crimp SJ, Howden SM, Stone RC, Jones DA (1998) Climate change in Queensland’s grazing lands. I. Approaches and climatic trends. The Rangeland Journal 20, 151–176.

McKeon G, Ash A, Hall W, Stafford Smith M (2000) Simulation of grazing strategies for beef production in north-eastern Queensland. In ‘Applications of seasonal climate forecasting in agricultural and natural ecosystems: the Australian experience’. (Eds G Hammer, N Nicholls, C Mitchell) pp. 227–252. (Kluwer Academic Press: Dordrecht, The Netherlands)

McKeon G, Cunningham GM, Hall WB, Henry BK, Owens JS, Stone GS, Wilcox DG (2004) Degradation and recovery episodes in Australia’s rangelands: An anthology. In ‘Pasture degradation and recovery in Australia’s rangelands: Learning from history’. (Eds G McKeon, WB Hall, BK Henry, GS Stone, IW Watson) pp. 87–172. (Queensland Department Natural Resources, Mines and Energy: Brisbane, Qld)

McKeon GM, Stone GS, Syktus JI, Carter JO, Flood NR, Ahrens DG, Bruget DN, Chilcott CR, Cobon DH, Cowley RA, Crimp SJ, Fraser GW, Howden SM, Johnston PW, Ryan JG, Stokes CJ, Day KA (2009) Climate change impacts on northern Australian rangeland livestock carrying capacity: a review of issues. The Rangeland Journal 31, 1–29.
Climate change impacts on northern Australian rangeland livestock carrying capacity: a review of issues.Crossref | GoogleScholarGoogle Scholar |

MLA (2013) ‘Australia’s beef industry: fast facts 2013.’ Available at http://www.mla.com.au/About-MLA/Cattle-sheep-goat-industries/Industry-overview/Cattle [Verified 21 August 2015]

O’Reagain PJ, Scanlan JC (2013) Sustainable management for rangelands in a variable climate: evidence and insights from northern Australia. Animal 7, 68–78.
Sustainable management for rangelands in a variable climate: evidence and insights from northern Australia.Crossref | GoogleScholarGoogle Scholar | 23031187PubMed |

O’Reagain P, Bushell J, Holloway C, Reid A (2009) Managing for rainfall variability: effect of grazing strategy on cattle production in a dry tropical savanna. Animal Production Science 49, 85–99.
Managing for rainfall variability: effect of grazing strategy on cattle production in a dry tropical savanna.Crossref | GoogleScholarGoogle Scholar |

O’Reagain P, Bushell J, Holmes B (2011) Managing for rainfall variability: long-term profitability of different grazing strategies in a northern Australian tropical savanna. Animal Production Science 51, 210–224.
Managing for rainfall variability: long-term profitability of different grazing strategies in a northern Australian tropical savanna.Crossref | GoogleScholarGoogle Scholar |

Pahl LI, Scanlan JC, Whish GL, Cowley RA, MacLeod ND (2013) Systematic management of stocking rates improves performance of northern Australian cattle properties in a variable climate. Tropical Grasslands 1, 230–234.
Systematic management of stocking rates improves performance of northern Australian cattle properties in a variable climate.Crossref | GoogleScholarGoogle Scholar |

Partridge I (1999) ‘Managing grazing in northern Australia: a grazier’s guide.’ Information Series QI99026. (Department of Primary Industries Queensland: Brisbane)

Scanlan JC, Hinton AW, McKeon GM, Day KA, Mott JJ (1994) Estimating safe carrying capacities of extensive cattle-grazing properties within tropical, semi-arid woodlands of north-eastern Australia. The Rangeland Journal 16, 64–76.
Estimating safe carrying capacities of extensive cattle-grazing properties within tropical, semi-arid woodlands of north-eastern Australia.Crossref | GoogleScholarGoogle Scholar |

Scanlan JC, MacLeod ND, O’Reagain PJ (2013) Scaling results up from a plot and paddock scale to a property: a case study from a long-term grazing experiment in northern Australia. The Rangeland Journal 35, 193–200.
Scaling results up from a plot and paddock scale to a property: a case study from a long-term grazing experiment in northern Australia.Crossref | GoogleScholarGoogle Scholar |

Stafford Smith DM (1996) Management of rangelands: paradigms at their limits. In ‘The ecology and management of grazing systems’. (Eds J Hodgson, AW Illius) pp. 325–357. (CAB International: Wallingford, UK)

Stafford Smith MS, Buxton R, McKeon GM, Ash AJ (2000) Seasonal climate forecasting and the management of rangelands: do production benefits translate into enterprise profits? In ‘Applications of seasonal climate forecasting in agricultural and natural ecosystems: the Australian experience’. (Eds G Hammer, N Nicholls, C Mitchell) pp. 271–289. (Kluwer Academic Press: Dordrecht, The Netherlands)

Tyler R (1997) ‘Drought management planning and supplementary feeding for beef cattle.’ (Department of Primary Industries Queensland: Brisbane)

Wilson AD, MacLeod ND (1991) Overgrazing in the rangelands: present or absent? Journal of Range Management 44, 475–482.
Overgrazing in the rangelands: present or absent?Crossref | GoogleScholarGoogle Scholar |