An economic decision model of wild rabbit Oryctolagus cuniculus control to conserve Australian native vegetation
Brian Cooke A F , Randall Jones B D and Wendy Gong C EA Invasive Animals Cooperative Research Centre, University of Canberra, ACT 2601, Australia.
B NSW Industry and Investment, Orange Agricultural Institute, Orange, NSW 2800, Australia.
C University of New England, Armidale, NSW 2351, Australia.
D Present address: Asian Development Bank, Mandaluyong City, Metro Manila, Philippines.
E Present address: University of New South Wales, Sydney, NSW 2052, Australia.
F Corresponding author: brian.cooke@canberra.edu.au
Wildlife Research 37(7) 558-565 https://doi.org/10.1071/WR09154
Submitted: 9 November 2009 Accepted: 16 September 2010 Published: 17 December 2010
Abstract
Context: Economic decision models are seldom used in developing policies for the cost-effective control of invasive species that threaten natural ecosystems. However, their potential value is shown using an example of European rabbits damaging native vegetation in Australia.
Aims: To better define the problem of rabbit damage, provide a sound theoretical basis for implementing cost-efficient strategies for rabbit control and show how resources available for ecosystem protection can be most effectively applied.
Methods: A dynamic economic decision model was developed, incorporating the costs and effectiveness of three methods for controlling rabbits among native vegetation to consider alternative management strategies. A monetary value on native vegetation was set using the ‘avoided’ cost of replanting trees on roadsides and from field data we described how capacity of plant communities to regenerate improves if rabbit numbers are reduced.
Key results: Model outputs indicated the best combinations of methods for cost-effective rabbit control and showed how the highest benefits could be gained in protecting natural vegetation.
Conclusions: The model provided a framework for deciding how limited resources might be used to greatest benefit for protecting native vegetation.
Implications: This methodology could apply to other invasive species, provided that natural assets can be given a justifiable monetary value, control costs and effectiveness can be determined and the impact of the pests on assets can be modelled as dynamic population processes.
Additional keywords: economic, decision, rabbit, Oryctolagus, conservation, vegetation.
References
Anon. (2002). ‘Victoria’s Native Vegetation Management: A Framework for Action.’ (The State of Victoria, Department of Natural Resources and Environment.) Available at www.nre.vic.gov.au [accessed June 2010].Bellman, R. E. (1957). ‘Dynamic Programming.’ (Princeton University Press: Princeton, NJ.)
Cooke, B. D. (1981). Rabbit control and conservation of native mallee vegetation on roadsides in South Australia. Australian Wildlife Research 8, 627–636.
| Rabbit control and conservation of native mallee vegetation on roadsides in South Australia.Crossref | GoogleScholarGoogle Scholar |
Cooke, B. D. (1987). The effects of rabbit grazing on the regeneration of sheoaks Allocasuarina verticillata and salt-water ti-trees Melaleuca halmaturorum in the Coorong National Park, South Australia. Australian Journal of Ecology 13, 11–20.
Cooke, B. D. (2002). Rabbit haemorrhagic disease: field epidemiology and the management of wild rabbit populations. Revue scientifique et technique Office international des Epizooties 21, 347–358.
| 1:STN:280:DC%2BD383jslelsw%3D%3D&md5=253521a7436924004e58b58715ac1b3eCAS |
Courant, P., and Porter, R. (1981). Averting expenditures and the cost of pollution. Journal of Environmental Economics and Management 8, 321–329.
| Averting expenditures and the cost of pollution.Crossref | GoogleScholarGoogle Scholar |
Fenner, F., and Fantini, B. (1999). ‘Biological control of vertebrate pests; the history of myxomatosis; an experiment in evolution.’ (CAB International: Wallingford, UK.)
Jones, R. E., and Medd, R. W. (2005). A methodology for evaluating risk and efficacy of weed management technologies. Weed Science 53, 505–514.
| A methodology for evaluating risk and efficacy of weed management technologies.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD2MXntFCqtro%3D&md5=b406c98d34a86d360db0610a81a9f2e6CAS |
Kennedy, J. O. S. (1981). Applications of dynamic programming to agriculture, forestry and fisheries. Review of Marketing and Agricultural Economics 23, 147–159.
Kennedy, J. O. S. (1986). ‘Dynamic Programming: Applications to Agriculture and Natural Resources.’ (Elsevier Applied Science Publishers: London.)
Kennedy, J. O. S. (1988). Principles of dynamic optimization in resource management. Agricultural Economics 2, 57–72.
| Principles of dynamic optimization in resource management.Crossref | GoogleScholarGoogle Scholar |
Lange, R. T., and Graham, C. R. (1983). Rabbits and the failure of regeneration in Australian arid-zone Acacia. Australian Journal of Ecology 8, 337–381.
Lockwood, M., Walpole, S., and Miles, C. (2000). ‘Economics of Remnant Native Vegetation Conservation on Private Property.’ (Land and Water Resource Research and Development Corporation: Canberra.)
Mutze, G., Bird, P., Cooke, B., and Henzell, R. (2008). Geographic and seasonal variation in the impact of rabbit haemorrhagic disease virus on European rabbits, Oryctolagus cuniculus, and rabbit damage in Australia. In ‘Lagomorph Biology: Evolution, Ecology and Conservation’. (Eds P. C. Alves, N. Ferrand and K. Hackländer.) pp. 279–293. (Springer-Verlag: Berlin.)
Parer, I. (1982). European rabbit Australia. In ‘CRC Handbook of Census Methods for Terrestrial Vertebrates’. (Ed. D. E. Davis.) pp. 136–138. (CRC Press: Boca Raton, FL.)
Sandell, P. (2006). Promoting woodland recovery in the Victorian mallee parks. Proceedings of the Royal Society of Victoria 118, 313–321.
Schirmer, J., and Field, J. (2000). ‘The Cost of Revegetation.’ (Natural Heritage Trust, Department of Environment, Water, Heritage and the Arts: Canberra.)
Sinden, J. A., and Worrell, A. C. (1979). ‘Unpriced Values: Decisions without Market Prices.’ (A. Wiley, Interscience: New York.)
Taylor, C. R. (1993). ‘Applications of Dynamic Programming to Agricultural Decision Problems.’ (Westview Press: Boulder, CO.)
Victorian Fauna and Flora Guarantee Act (1988). Version incorporating amendments to 1 January 2010. 88-47a036.pdf. Available at http://www.legislation.vic.gov.au [accessed May 2010].
Williams, C. K., and Moore, R. J. (1995). Effectiveness and cost-efficiency of control of the wild rabbit Orytolagus cuniculus (L.) by combinations of poisoning, ripping fumigation and maintenance fumigation. Wildlife Research 22, 253–269.
| Effectiveness and cost-efficiency of control of the wild rabbit Orytolagus cuniculus (L.) by combinations of poisoning, ripping fumigation and maintenance fumigation.Crossref | GoogleScholarGoogle Scholar |