Register      Login
Wildlife Research Wildlife Research Society
Ecology, management and conservation in natural and modified habitats
RESEARCH ARTICLE

When do predator exclusion fences work best? A spatially explicit modelling approach

C. Pacioni https://orcid.org/0000-0001-5115-4120 A B E * , M. S. Kennedy C D * and D. S. L. Ramsey A
+ Author Affiliations
- Author Affiliations

A Arthur Rylah Institute for Environmental Research, Department of Environment, Land, Water and Planning, 123 Brown Street, Heidelberg, Vic. 3084, Australia.

B School of Veterinary and Life Sciences, Murdoch University, 90 South Street, Murdoch, WA 6150, Australia.

C Department of Primary Industries and Regional Development, 3 Baron-Hay Court, South Perth, WA 6151, Australia.

D Present address: Department of Agriculture and Fisheries, 203 Tor Street, Toowoomba, Qld 4350, Australia.

E Corresponding author. Email: carlo.pacioni@gmail.com

Wildlife Research 48(3) 209-217 https://doi.org/10.1071/WR19192
Submitted: 14 October 2019  Accepted: 16 August 2020   Published: 27 November 2020

Abstract

Context: Exclusion fences are increasingly used to prevent interactions between predators (introduced and native) and assets such as endangered species or livestock. However, challenges remain in identifying when exclusion fences are an optimal investment and the intended outcome is likely to be achieved. The level of association with complementary methods of control that is needed is also unclear.

Aims: We aimed to quantify the interactions among factors that affect fencing efficiency, including the size of the fenced area, the fence permeability, the initial density of the predator population, and its survival of complementary control methods.

Methods: Using a spatially explicit, individual-based model, we simulated wild dog (dingo) populations as a proxy for describing predator dynamics inside a fenced area under different management practices and fence designs. We then fit a generalised linear model to the model outcomes to assess the effects of the four factors mentioned above.

Key results: Lethal control had a strong effect on wild dog density when the survival of control was lower than 0.5. Fences generally had an effect on wild dog density only when their permeability was lower than ~1% and their effect was most noticeable when the initial density was very low (<2 dogs per 100 km2), or when survival of control was very low (<0.5). Conversely, when the initial density was very high (~12 dogs per 100 km2), a fence with a low permeability (<1.5%) caused the paradoxical effect that wild dog density could be higher than that obtained with a more permeable fence. Wild dog eradication was possible only when survival of control was 0.25 or lower, except when either initial density or fence permeability were extremely low (<2 dogs per 100 km2 and <0.1% respectively).

Conclusions: Our results demonstrated that large exclusion fences can be an effective aid in managing predator populations. We recommend that this tool should be used as a preventive measure before predators establish a population inside the area targeted for exclusion, in tandem with lethal control, or when an initial marked reduction of predator density can be achieved. We also demonstrated that eradication can be achieved only when a narrow combination of parameters is met.

Implications: Land managers should carefully evaluate when and at what scale control tools should be deployed to control wild dog populations. Landscape application of exclusion fences faces the challenge of high maintenance to ensure low permeability, coupled with very high sustained suppression of wild dog density, which are unlikely to be feasible options in the long term. Conversely, the same control techniques could provide efficient asset protection at a smaller scale where fence maintenance and sufficient control effort can be sustained.

Keywords: dingo, HexSim, livestock predation, livestock attacks, pest control, population modelling, wild dog, wildlife management, cluster fence, cell fence.


References

Allee, W. (1931). ‘Animal Aggregations: a Study in General Sociology.’ (The University of Chicago Press: Chigaco, IL, USA.)

Allen, B. L. (2018). FOFI5M: Taking threatened species recovery to the next level. Restore, Regenerate, Revegetate , 1–2.

Allen, L., and Fleming, P. (2004). Review of canid management in Australia for the protection of livestock and wildlife: potential application to coyote management. Sheep & Goat Research Journal 19, 97–104.

Allen, B., and West, P. (2013). Influence of dingoes on sheep distribution in Australia. Australian Veterinary Journal 91, 261–267.
Influence of dingoes on sheep distribution in Australia.Crossref | GoogleScholarGoogle Scholar | 23782018PubMed |

Binks, B., Kancans, R., and Stenekes N. (2015). Wild dog management 2010 to 2014: national landholder survey results. ABARES report to client prepared for Australian Wool Innovation Ltd, Canberra, ACT, Australia.

Bode, M., and Wintle, B. (2010). How to build an efficient conservation fence. Conservation Biology 24, 182–188.
How to build an efficient conservation fence.Crossref | GoogleScholarGoogle Scholar | 19604295PubMed |

Bombaci, S., Pejchar, L., and Innes, J. (2018). Fenced sanctuaries deliver conservation benefits for most common and threatened native island birds in New Zealand. Ecosphere 9, e02497.
Fenced sanctuaries deliver conservation benefits for most common and threatened native island birds in New Zealand.Crossref | GoogleScholarGoogle Scholar |

Burnham, K. P., and Anderson, D. R. (1998). Practical use of the information-theoretic approach. In ‘Model Selection and Inference’. (Eds K. P. Burnham, and D. R. Anderson.) pp. 75–117. (Springer. New York, NY, USA)

Day, T., and MacGibbon, R. (2002). Escape behaviour and physical abilities of vertebrate pests towards electrified and non-electrified fences. Xcluder Pest Proof Fencing Company unpublished internal report. Xcluder Pest Proof Fencing Company Ltd, Cambridge, New Zealand.

Fleming, P. J., Allen, B. L., Allen, L. R., Ballard, G., Bengsen, A., Gentle, M. N., McLeod, L. J., Meek, P. D., and Saunders, G. R. (2014). Management of wild canids in Australia: free-ranging dogs and red foxes. In ‘Carnivores of Australia: Past, Present and Future’. (Eds A. Glen, and C. Dickman.) pp. 107–152. (CSIRO Publishing: Melbourne, Vic., Australia.)

Foley, J. A., DeFries, R., Asner, G. P., Barford, C., Bonan, G., Carpenter, S. R., Chapin, F. S., Coe, M. T., Daily, G. C., and Gibbs, H. K. (2005). Global consequences of land use. Science 309, 570–574.
Global consequences of land use.Crossref | GoogleScholarGoogle Scholar | 16040698PubMed |

Giles, J. (1980). The ecology of feral pigs in western New South Wales. Ph.D. Thesis. University of Sydney, Sydney, NSW, Australia.

Government of Western Australia (2018). ‘Funding to Fence out Wild Dogs.’ Available at https://www.mediastatements.wa.gov.au/Pages/McGowan/2018/02/Funding-to-fence-out-wild-dogs.aspx [verified February 2018].

Haque, M. Z., Reza, M. I. H., Rahim, S. A., Abdullah, M., Elfithri, R., and Mokhatar, M. B. (2015). Behavioral change due to climate change effects accelerate tiger human conflicts: a study on sundarbans mangrove forests, Bangladesh. International Journal of Conservation Science 6, 669–684.

Hayward, M. W., and Kerley, G. I. H. (2009). Fencing for conservation: restriction of evolutionary potential or a riposte to threatening processes? Biological Conservation 142, 1–13.
Fencing for conservation: restriction of evolutionary potential or a riposte to threatening processes?Crossref | GoogleScholarGoogle Scholar |

Hayward, M. W., and Somers, M. J. (2012). An introduction to fencing for conservation. In ‘Fencing for Conservation’. (Eds M. W. Hayward, and M. J. Somers.) pp. 1–6. (Springer: New York, NY, USA.)

Helmstedt, K. J., Possingham, H. P., Brennan, K. E., Rhodes, J. R., and Bode, M. (2014). Cost‐efficient fenced reserves for conservation: single large or two small? Ecological Applications 24, 1780–1792.
Cost‐efficient fenced reserves for conservation: single large or two small?Crossref | GoogleScholarGoogle Scholar | 29210237PubMed |

Jackson, S. M., Groves, C. P., Fleming, P. J., Aplin, K. P., Eldridge, M. D., Gonzalez, A., and Helgen, K. M. (2017). The wayward dog: is the Australian native dog or dingo a distinct species? Zootaxa 4317, 201–224.
The wayward dog: is the Australian native dog or dingo a distinct species?Crossref | GoogleScholarGoogle Scholar |

Kreplins, T., Kennedy, M., Adams, P., Bateman, B., Dundas, S., and Fleming, P. (2018). Fate of dried meat baits aimed at wild dog (Canis familiaris) control. Wildlife Research 45, 528–538.
Fate of dried meat baits aimed at wild dog (Canis familiaris) control.Crossref | GoogleScholarGoogle Scholar |

Legge, S., Woinarski, J. C., Burbidge, A. A., Palmer, R., Ringma, J., Radford, J. Q., Mitchell, N., Bode, M., Wintle, B., and Baseler, M. (2018). Havens for threatened Australian mammals: the contributions of fenced areas and offshore islands to the protection of mammal species susceptible to introduced predators. Wildlife Research 45, 627–644.
Havens for threatened Australian mammals: the contributions of fenced areas and offshore islands to the protection of mammal species susceptible to introduced predators.Crossref | GoogleScholarGoogle Scholar |

Madden, F. (2004). Creating coexistence between humans and wildlife: global perspectives on local efforts to address human–wildlife conflict. Human Dimensions of Wildlife 9, 247–257.
Creating coexistence between humans and wildlife: global perspectives on local efforts to address human–wildlife conflict.Crossref | GoogleScholarGoogle Scholar |

Morrant, D. S., Wurster, C. M., Johnson, C. N., Butler, J. R., and Congdon, B. C. (2017). Prey use by dingoes in a contested landscape: ecosystem service provider or biodiversity threat? Ecology and Evolution 7, 8927–8935.
Prey use by dingoes in a contested landscape: ecosystem service provider or biodiversity threat?Crossref | GoogleScholarGoogle Scholar | 29152188PubMed |

Murphy, E. C., Russell, J. C., Broome, K. G., Ryan, G. J., and Dowding, J. E. (2019). Conserving New Zealand’s native fauna: a review of tools being developed for the Predator Free 2050 programme. Journal of Ornithology 160, 883–892.
Conserving New Zealand’s native fauna: a review of tools being developed for the Predator Free 2050 programme.Crossref | GoogleScholarGoogle Scholar |

Norbury, G., Hutcheon, A., Reardon, J., and Daigneault, A. (2014). Pest fencing or pest trapping: a bio‐economic analysis of cost‐effectiveness. Austral Ecology 39, 795–807.
Pest fencing or pest trapping: a bio‐economic analysis of cost‐effectiveness.Crossref | GoogleScholarGoogle Scholar |

Olson, E. R., Van Deelen, T. R., Wydeven, A. P., Ventura, S. J., and Macfarland, D. M. (2015). Characterizing wolf–human conflicts in Wisconsin, USA. Wildlife Society Bulletin 39, 676–688.
Characterizing wolf–human conflicts in Wisconsin, USA.Crossref | GoogleScholarGoogle Scholar |

Pacioni, C., Kennedy, M., Berry, O., Stephens, D., and Schumaker, N. H. (2018). Spatially-explicit model for assessing wild dog control strategies in Western Australia. Ecological Modelling 368, 246–256.
Spatially-explicit model for assessing wild dog control strategies in Western Australia.Crossref | GoogleScholarGoogle Scholar | 29456284PubMed |

Pacioni, C., Ramsey, D. S. L., Schumaker, N. H., Kreplins, T., and Kennedy, M. S. (2020). A novel modelling framework to explicitly simulate predator interaction with poison baits. Wildlife Research , .
A novel modelling framework to explicitly simulate predator interaction with poison baits.Crossref | GoogleScholarGoogle Scholar |

Pickard, J. (2007). Predator-proof fences for biodiversity conservation: some lessons from dingo fences. In ‘Animals of Arid Australia: Out on their Own’. (Eds C. R. Dickman, D. Lunney, and S. Bergin.) pp. 197–207. (Royal Zoological Society of New South Wales: Sydney, NSW, Australia.)

Prowse, T. A. A., Bradshaw, C. J. A., Delean, S., Cassey, P., Lacy, R. C., Wells, K., Aiello-Lammens, M. E., Akçakaya, H. R., and Brook, B. W. (2016). An efficient protocol for the global sensitivity analysis of stochastic ecological models. Ecosphere 7, e01238.
An efficient protocol for the global sensitivity analysis of stochastic ecological models.Crossref | GoogleScholarGoogle Scholar |

Radford, J. Q., Woinarski, J. C., Legge, S., Baseler, M., Bentley, J., Burbidge, A. A., Bode, M., Copley, P., Dexter, N., and Dickman, C. R. (2018). Degrees of population-level susceptibility of Australian terrestrial non-volant mammal species to predation by the introduced red fox (Vulpes vulpes) and feral cat (Felis catus). Wildlife Research 45, 645–657.
Degrees of population-level susceptibility of Australian terrestrial non-volant mammal species to predation by the introduced red fox (Vulpes vulpes) and feral cat (Felis catus).Crossref | GoogleScholarGoogle Scholar |

Ramsey, D. S., and Wilson, J. C. (2000). Towards ecologically based baiting strategies for rodents in agricultural systems. International Biodeterioration & Biodegradation 45, 183–197.
Towards ecologically based baiting strategies for rodents in agricultural systems.Crossref | GoogleScholarGoogle Scholar |

Remote Area Planning and Development Board (RAPAD) (2018). Available at www.rapad.com.au [verified 1 May 2018].

Ringma, J. L., Wintle, B., Fuller, R. A., Fisher, D., and Bode, M. (2017). Minimizing species extinctions through strategic planning for conservation fencing. Conservation Biology 31, 1029–1038.
Minimizing species extinctions through strategic planning for conservation fencing.Crossref | GoogleScholarGoogle Scholar | 28248429PubMed |

Russell, J. C., Innes, J. G., Brown, P. H., and Byrom, A. E. (2015). Predator-free New Zealand: conservation country. Bioscience 65, 520–525.
Predator-free New Zealand: conservation country.Crossref | GoogleScholarGoogle Scholar | 26955079PubMed |

Schumaker, N. H., and Brookes, A. (2018). HexSim: a modeling environment for ecology and conservation. Landscape Ecology 33, 197–211.
HexSim: a modeling environment for ecology and conservation.Crossref | GoogleScholarGoogle Scholar | 29545713PubMed |

Taylor, C. M., and Hastings, A. (2005). Allee effects in biological invasions. Ecology Letters 8, 895–908.
Allee effects in biological invasions.Crossref | GoogleScholarGoogle Scholar |

Thomson, P. (1986). The effectiveness of aerial baiting for the control of dingoes in north-western Australia. Wildlife Research 13, 165–176.
The effectiveness of aerial baiting for the control of dingoes in north-western Australia.Crossref | GoogleScholarGoogle Scholar |

Thomson, P., Rose, K., and Kok, N. (1992). The behavioural ecology of dingoes in north-western Australia. V. Population dynamics and variation in the social system. Wildlife Research 19, 565–583.
The behavioural ecology of dingoes in north-western Australia. V. Population dynamics and variation in the social system.Crossref | GoogleScholarGoogle Scholar |

Torres, D. F., Oliveira, E. S., and Alves, R. R. N. (2018). Conflicts between humans and terrestrial vertebrates: a global review. Tropical Conservation Science 11, 1–15.
Conflicts between humans and terrestrial vertebrates: a global review.Crossref | GoogleScholarGoogle Scholar |

Trinkel, M., and Angelici, F. M. (2016). The decline in the lion population in Africa and possible mitigation measures. (Ed. F. M. Angelici.) In ‘Problematic Wildlife’. pp. 45–68. (Springer: Cham, Switzerland.)

Zeileis, A., Kleiber, C., and Jackman, S. (2008). Regression models for count data in R. Journal of Statistical Software 27, 1–25.
Regression models for count data in R.Crossref | GoogleScholarGoogle Scholar |