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

Predicting the occurrence of the quokka, Setonix brachyurus (Macropodidae : Marsupialia), in Western Australia’s northern jarrah forest

Matt W. Hayward A B C D , Paul J. de Tores B , Michael J. Dillon C and Peter B. Banks A
+ Author Affiliations
- Author Affiliations

A School of Biological, Earth and Environmental Science, University of New South Wales, Sydney, NSW 2052, Australia.

B Department of Conservation and Land Management, Wildlife Research Centre, PO Box 51, Wanneroo, WA 6946, Australia.

C Department of Conservation and Land Management, Dwellingup Research Centre, Banksiadale Road, Dwellingup, WA 6213, Australia.

D Corresponding author. Present address: Mammal Research Institute, Polish Academy of Science, 17-230 Bialowieza, Poland. Email: hayers111@aol.com

Wildlife Research 34(3) 194-199 https://doi.org/10.1071/WR06161
Submitted: 24 November 2006  Accepted: 29 March 2007   Published: 6 June 2007

Abstract

The quokka, Setonix brachyurus, is a medium-sized, macropodid marsupial that is endemic to south-western Australia. It has declined markedly in its distribution and abundance since the early 1930s and is listed as vulnerable under IUCN criteria. The presence or absence of quokka populations at 66 sites in the northern jarrah forest of Australia was investigated using generalised linear models (GLM). We hypothesised that fox control and the presence of a mosaic of post-fire seral stages within Agonis linearifolia swamp vegetation were important in predicting the presence of quokkas. The number of poison meat baits delivered per hectare, the average number of years since the swamps burnt and the number of post-fire age classes within the swamps (mosaic value) were used as explanatory variables. Two models had substantial support (ΔAICc < 2), with the best approximating model including the variables ‘baiting’ and ‘swamp age’, and the second-best model including the additional variable ‘swamp mosaic value’. The two best models had Akaike weights (weight of evidence as being the best model of the data) of 0.465 and 0.308 respectively. We used an information-theoretic approach and multimodel inference to determine the best approximating model of baiting, swamp age and swamp mosaic, and Akaike weights to assess model fit and to rank variable importance. Baiting had a model average parameter estimate of 98, swamp age 79 and a mosaic of swamp age classes 42, implying that baiting was more than twice as important as the number of swamp ages classes at a site in predicting the occurrence of quokkas. Evidence from our analysis therefore supports previous studies that concluded that continued fox control and the maintenance of a mosaic of early seral stage (<10 years since fire) and long unburnt habitat (>19 years since fire) are essential for its conservation.


Acknowledgements

This project was funded by the Department of Conservation and Land Management (DCLM) and Alcoa World Alumina Australia and MWH was funded by an Australian Postgraduate Research Award. The project was approved by CALMScience Ethics Committee Approval Number CAEC 1/97 and subsequent renewals. MWH thanks the friends and family who assisted in the field (particularly Nick Valentine). I. Abbott, N. Marlow, J. Hayward, E. Jefferys, J. Taylor, K. Ross, G. Dawson, M. McCarthy, D. Saunders and an anonymous reviewer provided valuable comments on this paper.


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