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You are here: Home > Journals > AN > EA08286
RESEARCH ARTICLE
Contents Vol 49(10)

Economic value of grazing vegetative wheat (Triticum aestivum L.) crops in mixed-farming systems of Western Australia

Graeme J. Doole A C D , Andrew D. Bathgate B and Michael J. Robertson C
+ Author Affiliations
- Author Affiliations

A School of Agricultural and Resource Economics, Faculty of Natural and Agricultural Sciences, University of Western Australia, 35 Stirling Highway, Crawley, WA 6009, Australia.

B Farming Systems Analysis Service, 41 Trebor Road, Cuthbert, WA 6330, Australia.

C CSIRO Sustainable Ecosystems, Underwood Avenue, Floreat, WA 6014, Australia.

D Corresponding author. Email: gdoole@mngt.waikato.ac.nz

Animal Production Science 49(10) 807-815 https://doi.org/10.1071/EA08286
Submitted: 27 November 2008  Accepted: 25 March 2009   Published: 16 September 2009

Abstract

Livestock production in Western Australian mixed-farming systems has traditionally been constrained by a profound scarcity of feed in autumn–early winter when crop stubbles and pasture residues from the previous growing season have been exhausted. This study investigates the profitability of partially filling this ‘feed gap’ through the grazing of vegetative wheat crops. Whole-farm bioeconomic modelling is used to provide insight into the relative value of grazing and grain production in both low- and high-rainfall areas of Western Australia. Dual-purpose wheat crops are a valuable source of feed in high-rainfall areas as they provide an affordable alternative to expensive grain supplements for a short period in winter. This also allows annual pastures to establish more vigorously by reducing grazing pressure on young plants. Model output suggests farm profit can increase by over 10% with the grazing of vegetative wheat crops in high-rainfall regions; however, these results are logically shown to be strongly related to the assumed rate of yield loss. In contrast, at the parameter values used in this study, grazing wheats are unlikely to be profitable in low-rainfall environments due to depressed crop production and the extended feed gap experienced in these areas. Higher grain prices unequivocally lower the relative advantage of grazing activity since this elevates the cost of foregone grain yield.

Additional keywords: dual-purpose wheat, grazing cereals, whole-farm modelling.




1 This substitution effect may not occur in those farming systems in which barley crops are also grazed by livestock.

Acknowledgements

The authors would like to acknowledge the provision of funding by Australian Wool Innovation Limited, Grains Research & Development Corporation, Land & Water Australia, and Meat & Livestock Australia. The advice and provision of information by Hugh Dove, Ross Kingwell, David Pannell, and Jim Virgona is also greatly appreciated.


References


Australian Bureau of Agricultural and Resource Economics (2008) Australian crop report no. 146, Australian Bureau of Agricultural and Resource Economics, Canberra.

Coleman TF, Li Y (1996) An interior trust region approach for nonlinear minimisation subject to bounds. SIAM Journal on Optimization 6, 418–445.
Crossref | GoogleScholarGoogle Scholar | open url image1

Ewing MA , Pannell DJ (1987) Development of regional pasture research priorities using mathematical programming. In ‘Temperate pastures: their production, use, and management’. (Eds JL Wheeler, CJ Pearson, GE Robards) pp. 586–589. (CSIRO: Canberra)

Ewing MA , Flugge FA , Kingwell RS (2005) The benefits and challenges of crop-livestock integration in Australian agriculture. CRC for Plant-Based Management of Dryland Salinity SEA, Working Paper no. 2003, Perth.

Farmlink (2006) ‘Research priority: rotations for mixed farming systems.’ (Farmlink: Sydney)

Forster HC, Vasey AJ (1931) Grazing cereal crops. Journal of the Department of Agriculture, Victoria 29, 369–372. open url image1

Jarque CM, Bera AK (1980) Efficient tests for normality, heteroskedasticity, and serial independence of regression residuals. Economics Letters 6, 255–259.
Crossref | GoogleScholarGoogle Scholar | open url image1

Keating BA, Carberry PS, Hammer GL, Probert ME, Robertson MJ , et al . (2003) An overview of APSIM, a model designed for farming systems simulation. European Journal of Agronomy 18, 267–288.
Crossref | GoogleScholarGoogle Scholar | open url image1

Kingwell RS , Pannell DJ (Eds) (1987) ‘MIDAS, a bioeconomic model of a dryland farming system.’ (Pudoc: Wageningen, The Netherlands)

Kopke E, Young J, Kingwell RK (2007) The relative profitability and environmental impacts of different sheep systems in a Mediterranean environment. Agricultural Systems 86, 85–94. open url image1

Miranda MJ , Fackler PL (2002) ‘Applied computational economics and finance.’ (MIT Press: Cambridge)

Pannell DJ, Ewing MA (2006) Managing secondary dryland salinity: options and challenges. Agricultural Water Management 80, 41–56.
Crossref | GoogleScholarGoogle Scholar | open url image1

Pumphrey FV (1970) Semidwarf winter wheat response to early spring clipping and grazing. Agronomy Journal 62, 641–643. open url image1

Virgona JM, Gummer FAJ, Angus JF (2006) Effects of grazing on wheat growth, yield, development, water use, and nitrogen use. Australian Journal of Agricultural Research 57, 1307–1319.
Crossref | GoogleScholarGoogle Scholar | open url image1